JP6764128B2 - Sanitary cleaning equipment - Google Patents

Description

Aspects of the present invention generally relate to a sanitary cleaning device, specifically, a sanitary cleaning device that cleans a user's "tail" or the like sitting on a Western-style seated toilet with water.

In tap water used as cleaning water for sanitary cleaning equipment, bacteria are reduced by killing or inactivating bacteria (microorganisms) that may cause illness or putrefaction with chlorine. At present, bacteria can be removed to a level that does not harm the human body, but it is not possible to completely remove bacteria contained in tap water only by mixing chlorine. With the recent trend toward cleanliness, cleaning water with less bacteria is required, and it is proposed that the sanitary cleaning equipment be provided with an ultraviolet irradiation part that irradiates the cleaning water with ultraviolet rays to further reduce the bacteria contained in the cleaning water. (Patent Document 1).

The ultraviolet irradiation unit generally includes a flow path through which water flows, an irradiation window provided in the flow path, and a light emitting unit that irradiates water flowing in the flow path through the irradiation window with ultraviolet rays. Inorganic glass such as quartz glass, which has a high transmittance for ultraviolet rays, is used for the irradiation window. In such an ultraviolet irradiation section, when the water flowing in the flow path dries, minerals such as calcium, magnesium, and silica contained in the water are deposited as scale on the surface of the irradiation window in contact with water. In some cases. Such scale reduces the transmittance of ultraviolet rays and causes deterioration of the effect of reducing bacteria.

Therefore, in a sanitary cleaning device provided with an ultraviolet irradiation unit, it is desired to suppress deterioration in the performance of the ultraviolet irradiation unit due to the generation of water stains.

Special Fairness 05-004499 Gazette

The present invention has been made based on the recognition of such a problem, and an object of the present invention is to provide a sanitary cleaning device that suppresses deterioration of the performance of an ultraviolet irradiation unit.

The first invention has a nozzle for discharging water toward a local part of the human body, a water guide portion having a pipeline from a water supply source to the nozzle, and guiding water supplied from the water supply source to the nozzle, and the water guide. A vacuum breaker that is provided on the path of the water guide and takes in air into the pipeline when there is no flow of water in the water guide, and a vacuum breaker that is provided on the path of the water guide upstream of the vacuum breaker and provides water. The sanitary cleaning device is provided with an ultraviolet irradiation unit having a flow path for flowing water and a light emitting unit for irradiating water flowing in the flow path with ultraviolet rays through an irradiation window.

According to this sanitary cleaning device, since the ultraviolet irradiation part is provided on the upstream side of the vacuum breaker, even if water escapes in the water guide part on the downstream side of the vacuum breaker, the water in the flow path of the ultraviolet irradiation part. It is possible to prevent the water from coming out and allow water to stay in the flow path. As a result, it is possible to suppress the drying of water on the surface of the irradiation window and prevent the precipitation of water stains on the irradiation window. Therefore, it is possible to suppress deterioration of the effect of reducing bacteria in the ultraviolet irradiation portion.

The second invention is a sanitary cleaning apparatus according to the first invention, further comprising a heating unit for heating water, which is provided on the path of the water guiding unit on the downstream side of the ultraviolet irradiation unit. Is.

According to this sanitary cleaning device, it is possible to suppress the generation of scale in the irradiation window as compared with the case where water having a relatively high temperature heated by the heating unit is supplied to the ultraviolet irradiation unit. Therefore, as compared with the case where the heated water is supplied, it is possible to further suppress the deterioration of the performance of the ultraviolet irradiation portion due to the generation of water stains.

In the third invention, in the first or second invention, the flow path is tubular, the irradiation window is provided on the side surface of the flow path, and the light emitting portion flows in the flow path. It is a sanitary cleaning device characterized in that the ultraviolet rays are irradiated in a direction intersecting the direction of water, and the irradiation window and the light emitting portion are arranged below the vertical direction of the flow path in an installed state.

According to this sanitary cleaning device, even if the water in the flow path starts to dry due to non-use for a long time, the water stays on the irradiation window until relatively last, and the water stays on the surface of the irradiation window. It is possible to suppress drying. Therefore, deterioration of the effect of reducing bacteria in the ultraviolet irradiation portion can be further suppressed.

A fourth aspect of the invention is the first or second aspect, wherein the flow path is tubular, the irradiation window is provided at one end of the flow path, and the light emitting portion flows in the flow path. Sanitary cleaning characterized in that the ultraviolet rays are irradiated in a direction parallel to the direction of water, and the irradiation window and the light emitting portion are arranged so that the irradiation direction of the ultraviolet rays faces horizontally or upward in the installed state. It is a device.

According to this sanitary cleaning device, even if the water in the flow path starts to dry due to non-use for a long time, the water stays on the irradiation window until relatively last, and the water stays on the surface of the irradiation window. It is possible to suppress drying. Therefore, deterioration of the effect of reducing bacteria in the ultraviolet irradiation portion can be further suppressed. In addition, since ultraviolet rays are irradiated in a direction parallel to the direction of water flowing in the flow path, the water flowing in the flow path can be irradiated with ultraviolet rays for a relatively long time, and the performance of reducing bacteria is improved. You can also do it.

According to the aspect of the present invention, there is provided a sanitary cleaning device that suppresses deterioration of the performance of the ultraviolet irradiation unit.

It is a perspective view which shows the toilet apparatus provided with the sanitary cleaning apparatus which concerns on embodiment of this invention. It is a block diagram which shows the main part structure of the sanitary cleaning apparatus which concerns on this embodiment. 3 (a) and 3 (b) are a cross-sectional view and an exploded cross-sectional view showing the ultraviolet irradiation portion according to the present embodiment. It is a timing chart which illustrates the specific example of the operation of the sanitary cleaning apparatus which concerns on this embodiment. 5 (a) and 5 (b) are cross-sectional views showing a modified example of the ultraviolet irradiation portion according to the present embodiment. 6 (a) and 6 (b) are cross-sectional views showing a modified example of the ultraviolet irradiation portion according to the present embodiment. 7 (a) and 7 (b) are cross-sectional views showing a modified example of the ultraviolet irradiation portion according to the present embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. In each drawing, similar components are designated by the same reference numerals and detailed description thereof will be omitted as appropriate.
FIG. 1 is a perspective view showing a toilet device provided with a sanitary cleaning device according to an embodiment of the present invention.
As shown in FIG. 1, the toilet device includes a Western-style sitting toilet bowl (hereinafter, simply referred to as a “toilet bowl” for convenience of explanation) 800, and a sanitary cleaning device 100 provided on the Western-style toilet bowl. The sanitary cleaning device 100 has a casing 400, a toilet seat 200, and a toilet lid 300. The toilet seat 200 and the toilet lid 300 are pivotally supported with respect to the casing 400 so as to be openable and closable.

Inside the casing 400, there is a built-in body cleaning function unit that realizes cleaning of the "buttocks" of the user sitting on the toilet seat 200. Further, for example, the casing 400 is provided with a seating detection sensor 404 that detects that the user has sat on the toilet seat 200. When the seating detection sensor 404 detects a user sitting on the toilet seat 200, when the user operates an operation unit 500 (see FIG. 2) such as a remote controller, a cleaning nozzle (for convenience of the following description, simply "nozzle"). 473) can be advanced into the bowl 801 of the toilet bowl 800. In the sanitary cleaning device 100 shown in FIG. 1, the nozzle 473 represents a state in which the nozzle 473 has advanced into the bowl 801.

The nozzle 473 discharges water toward the local part of the human body to clean the local part of the human body. A bidet cleaning spout 474a and a buttocks cleaning spout 474b are provided at the tip of the nozzle 473. The nozzle 473 can inject water from the bidet washing spout 474a provided at the tip thereof to wash a female local part of a woman sitting on the toilet seat 200. Alternatively, the nozzle 473 can inject water from the buttocks washing spout 474b provided at the tip thereof to wash the "buttocks" of the user sitting on the toilet seat 200. The term "water" in the specification of the present application includes not only cold water but also heated hot water.

The mode for washing the "buttocks" includes, for example, "buttock washing" and "soft washing" in which the "buttocks washing" is gently washed with a softer stream of water than the "buttocks washing". The nozzle 473 can perform, for example, "bidet cleaning", "buttock cleaning", and "soft cleaning".

In the nozzle 473 shown in FIG. 1, the bidet cleaning spout port 474a is provided on the tip side of the nozzle 473 with respect to the buttocks cleaning spout port 474b, but the installation positions of the bidet cleaning spout port 474a and the buttocks cleaning spout port 474b. Is not limited to this. The bidet cleaning spout 474a may be provided on the rear end side of the nozzle 473 with respect to the buttocks cleaning spout 474b. Further, although the nozzle 473 shown in FIG. 1 is provided with two spouts, three or more spouts may be provided.

FIG. 2 is a block diagram showing a main configuration of the sanitary cleaning device according to the present embodiment.
FIG. 2 also shows the main components of the water channel system and the electrical system.
As shown in FIG. 2, the sanitary cleaning device 100 has a water guiding unit 20. The water conveyance unit 20 has a pipeline 20a from a water supply source 10 such as a water supply or a water storage tank to a nozzle 473. The water guide unit 20 guides the water supplied from the water supply source 10 to the nozzle 473 through the pipeline 20a. The pipeline 20a is formed by, for example, each part such as the solenoid valve 431, the heat exchanger unit 440, and the flow path switching part 472 described below, and a plurality of pipes connecting these parts.

A solenoid valve 431 is provided on the upstream side of the water guiding portion 20. The solenoid valve 431 is a solenoid valve that can be opened and closed, and controls the supply of water based on a command from a control unit 405 provided inside the casing 400. In other words, the solenoid valve 431 opens and closes the pipeline 20a. By opening the solenoid valve 431, the water supplied from the water supply source 10 flows into the pipeline 20a.

A pressure regulating valve 432 is provided downstream of the solenoid valve 431. The pressure regulating valve 432 adjusts the pressure in the pipeline 20a to a predetermined pressure range when the water supply pressure is high. A check valve 433 is provided downstream of the pressure regulating valve 432. The check valve 433 suppresses the backflow of water to the upstream side of the check valve 433 when the pressure in the pipeline 20a drops.

A heat exchanger unit 440 (heating unit) is provided downstream of the check valve 433. The heat exchanger unit 440 has a heater and heats the water supplied from the water supply source 10 to raise the temperature to, for example, a specified temperature. That is, the heat exchanger unit 440 produces hot water.

The heat exchanger unit 440 of the present embodiment is an instant heating type (instantaneous type) heat exchanger using, for example, a ceramic heater, and takes less time than a hot water storage heating type heat exchanger using a hot water storage tank. The water can be heated to a specified temperature. The heat exchanger unit 440 is not limited to the instantaneous heating type heat exchanger, and may be a hot water storage heating type heat exchanger. Further, the heating unit is not limited to the heat exchanger, and may be one using another heating method, for example, one using microwave heating.

The heat exchanger unit 440 is connected to the control unit 405. The control unit 405 raises the temperature of water to the temperature set by the operation unit 500 by controlling the heat exchanger unit 440 in response to the operation of the operation unit 500 by the user, for example.

A flow rate sensor 442 is provided downstream of the heat exchanger unit 440. The flow rate sensor 442 detects the flow rate of the water discharged from the heat exchanger unit 440. That is, the flow rate sensor 442 detects the flow rate of water flowing in the pipeline 20a. The flow rate sensor 442 is connected to the control unit 405. The flow rate sensor 442 inputs the flow rate detection result to the control unit 405.

An electrolytic cell unit 450 is provided downstream of the flow rate sensor 442. The electrolytic cell unit 450 produces a liquid (functional water) containing hypochlorous acid from tap water by electrolyzing the tap water flowing inside. The electrolytic cell unit 450 is connected to the control unit 405. The electrolytic cell unit 450 generates functional water based on the control by the control unit 405.

The functional water generated in the electrolytic cell unit 450 may be, for example, a solution containing metal ions such as silver ions and copper ions. Alternatively, the functional water generated in the electrolytic cell unit 450 may be a solution containing electrolytic chlorine, ozone, or the like. Alternatively, the functional water generated in the electrolytic cell unit 450 may be acidic water or alkaline water.

A vacuum breaker (VB) 452 is provided downstream of the electrolytic cell unit 450. The vacuum breaker 452 has, for example, a flow path for flowing water, an intake port for taking in air into the flow path, and a valve mechanism for opening and closing the intake port. The valve mechanism closes the intake port when water is flowing in the flow path, and opens the intake port when the flow of water is stopped to take in air into the flow path. That is, the vacuum breaker 452 takes in air into the pipeline 20a when there is no water flow in the water conveyance portion 20. For the valve mechanism, for example, a float valve is used.

The vacuum breaker 452 takes in air into the pipe line 20a as described above, thereby promoting drainage of a portion of the pipe line 20a downstream of the vacuum breaker 452, for example. The vacuum breaker 452 promotes drainage of the nozzle 473, for example. In this way, the vacuum breaker 452 drains the water in the nozzle 473 and takes in the air in the nozzle 473, so that, for example, the washing water in the nozzle 473 and the sewage collected in the bowl 801 can be collected from the water supply source 10 ( Suppresses backflow to the clean water) side.

A pressure modulator 454 is provided downstream of the vacuum breaker 452. The pressure modulator 454 gives pulsation or acceleration to the flow of water in the pipeline 20a of the water conveyance section 20, and is discharged from the bidet washing spout 474a of the nozzle 473, the tail washing spout 474b, and the water spouting section of the nozzle cleaning chamber 478. Gives pulsation to the water. That is, the pressure modulator 454 fluctuates the flow state of the water flowing in the pipeline 20a. The pressure modulator 454 is connected to the control unit 405. The pressure modulator 454 fluctuates the flow state of water based on the control by the control unit 405.

A flow rate adjusting unit 471 is provided downstream of the pressure modulation device 454. The flow rate adjusting unit 471 adjusts the water force (flow rate). A flow path switching unit 472 is provided downstream of the flow rate adjusting unit 471. The flow path switching unit 472 opens / closes and switches the water supply to the nozzle 473 and the nozzle cleaning chamber 478. The flow rate adjusting unit 471 and the flow path switching unit 472 may be provided as one unit. The flow rate adjusting unit 471 and the flow path switching unit 472 are connected to the control unit 405. The operation of the flow rate adjusting unit 471 and the flow path switching unit 472 is controlled by the control unit 405.

A nozzle 473, a nozzle cleaning chamber 478, and a spray nozzle 479 are provided downstream of the flow path switching unit 472. The nozzle 473 receives a driving force from the nozzle motor 476 and moves forward and backward into the bowl 801 of the toilet bowl 800. That is, the nozzle motor 476 advances and retreats the nozzle 473 based on a command from the control unit 405.

The nozzle cleaning chamber 478 cleans the outer peripheral surface (body) of the nozzle 473 by injecting functional water or water from a water discharge portion provided inside the nozzle cleaning chamber 478. The spray nozzle 479 makes the washing water and the functional water into a mist and sprays them onto the bowl 801. In this example, a spray nozzle 479 is provided separately from the nozzle 473 for cleaning the human body. Not limited to this, the nozzle 473 may be provided with a spout for spraying the mist-like liquid onto the bowl 801.

Further, downstream of the flow path switching portion 472, a buttocks cleaning flow path 21, a soft cleaning flow path 22, and a bidet cleaning flow path 23 are provided. The buttocks cleaning flow path 21 and the soft cleaning flow path 22 guide the water supplied from the water supply source 10 via the water guiding unit 20 and the functional water generated in the electrolytic cell unit 450 to the buttocks cleaning spout 474b. The bidet cleaning flow path 23 guides the water supplied from the water supply source 10 via the water guiding unit 20 and the functional water generated in the electrolytic cell unit 450 to the bidet cleaning spout 474a.

Further, a surface cleaning flow path 24 and a spray flow path 25 are provided downstream of the flow path switching portion 472. The surface cleaning flow path 24 guides the water supplied from the water supply source 10 via the water guiding portion 20 and the functional water generated in the electrolytic cell unit 450 to the water discharge portion of the nozzle cleaning chamber 478. The spray flow path 25 guides the water supplied from the water supply source 10 via the water guide section 20 and the functional water generated in the electrolytic cell unit 450 to the spray nozzle 479.

By controlling the flow path switching unit 472, the control unit 405 controls each flow of the buttocks cleaning flow path 21, the soft cleaning flow path 22, the bidet cleaning flow path 23, the surface cleaning flow path 24, and the spray flow path 25. Switch the opening and closing of the road. In this way, the flow path switching unit 472 is in a state where each of the plurality of water spouts such as the bidet cleaning spout 474a, the tail cleaning spout 474b, the nozzle cleaning chamber 478, and the spray nozzle 479 communicates with the pipeline 20a. And a state in which communication with the pipeline 20a is not performed.

Further, an ultraviolet irradiation unit 460 is provided between the check valve 433 and the heat exchanger unit 440. The ultraviolet irradiation unit 460 irradiates the water flowing in the pipeline 20a with ultraviolet rays. The ultraviolet irradiation unit 460 kills or inactivates at least a part of the bacteria contained in the water flowing in the conduit 20a by, for example, irradiation with ultraviolet rays. As a result, the ultraviolet irradiation unit 460 reduces the number of living bacteria contained in the water flowing in the pipeline 20a. The ultraviolet irradiation unit 460 sterilizes the washing water by, for example, irradiating with ultraviolet rays. The ultraviolet irradiation unit 460 is connected to the control unit 405. The ultraviolet irradiation unit 460 irradiates ultraviolet rays based on the control by the control unit 405.

The control unit 405 is supplied with electric power from the power supply circuit 401, and based on signals from the human body detection sensor 403, the seating detection sensor 404, the flow rate sensor 442, the operation unit 500, and the like, the electromagnetic valve 431 and the heat exchanger. It controls the operation of the unit 440, the electrolytic tank unit 450, the pressure modulator 454, the ultraviolet irradiation unit 460, the flow rate adjusting unit 471, the flow path switching unit 472, the nozzle motor 476, and the like.

As shown in FIG. 1, the human body detection sensor 403 is provided so as to be embedded in a recessed portion 409 formed on the upper surface of the casing 400, and detects a user (human body) approaching the toilet seat 200. In addition, a transmission window 310 is provided at the rear of the toilet lid 300. Therefore, when the toilet lid 300 is closed, the human body detection sensor 403 can detect the presence of the user through the transmission window 310. The control unit 405 automatically opens the toilet lid 300 in response to the detection of the user by the human body detection sensor 403, for example.

In addition, the casing 400 has various types such as a "warm air drying function", a "deodorizing unit", and an "indoor heating unit" that blow warm air toward the "buttocks" of the user sitting on the toilet seat 200 to dry them. A mechanism may be provided as appropriate. At this time, an exhaust port 407 from the deodorizing unit and an exhaust port 408 from the indoor heating unit are appropriately provided on the side surface of the casing 400. However, in the present invention, the sanitary cleaning function unit and other additional function units may not necessarily be provided.

3 (a) and 3 (b) are a cross-sectional view and an exploded cross-sectional view showing the ultraviolet irradiation portion according to the present embodiment.
As shown in FIGS. 3 (a) and 3 (b), the ultraviolet irradiation unit 460 has a flow path 461 and a light emitting element 462 (light emitting unit). The flow path 461, for example, allows the water sent from the check valve 433 to flow inside and sends it to the heat exchanger unit 440. The light emitting element 462 irradiates the water flowing through the flow path with ultraviolet rays. The wavelength of the ultraviolet rays emitted by the light emitting element 462 is, for example, 200 nm or more and 400 nm or less. It is preferably 250 nm. As a result, bacteria contained in the water flowing through the flow path 461 can be appropriately reduced. The light emitting element 462 is, for example, an LED (Light Emitting Diode). The light emitting element 462 is not limited to the LED, and may be, for example, an LD (Laser Diode) or an OLED (Organic Light Emitting Diode).

The flow path 461 is, for example, cylindrical. The flow path 461 may have another tubular shape such as a square tubular shape. An opening 461a is provided at one end of the flow path 461. An opening 461b is provided at the other end of the flow path 461. The flow path 461 allows water to flow between the opening 461a and the opening 461b. The opening 461a is connected to, for example, a check valve 433. The opening 461b is connected to, for example, the heat exchanger unit 440. As a result, the water exiting the check valve 433 enters the flow path 461 through the opening 461a and flows into the heat exchanger unit 440 through the opening 461b. That is, the flow path 461 forms a part of the pipeline 20a. In the flow path 461, water flows from the opening 461a toward the opening 461b. On the contrary, water may flow from the opening 461b toward the opening 461a.

The opening 461b faces the same direction as the extending direction of the flow path 461. On the other hand, the opening 461a faces a direction orthogonal to the extending direction of the flow path 461. That is, in this example, the flow path 461 is a substantially L-shaped pipeline. The shape of the flow path 461 is not limited to this, and may be any tubular shape capable of allowing water to flow inside.

Further, an opening 461c is further provided at one end of the flow path 461 where the opening 461a is provided. The opening 461c faces the same direction as the extending direction of the flow path 461. A recess 461d is provided on the outer edge of the opening 461c. The irradiation window 463 is fitted in the recess 461d. The shape of the irradiation window 463 is substantially the same as the shape of the recess 461d. The irradiation window 463 is transparent to the ultraviolet rays emitted by the light emitting element 462. The irradiation window 463 causes the ultraviolet rays of the light emitting element 462 arranged outside the flow path 461 to enter the inside of the flow path 461. Inorganic glass such as quartz glass is used for the irradiation window 463.

As described above, in this example, the light emitting element 462 is provided outside the flow path 461. Not limited to this, for example, when the light emitting element 462 is sealed with a package such as resin or metal, at least a part of the light emitting element 462 may be arranged in the flow path 461. In this case, the irradiation window 463 may be provided in the package of the light emitting element 462. As described above, the light emitting element 462 (light emitting unit) may have an irradiation window 463.

The recess 461d is further provided with a recess 461e. The recess 461e is an annular shape surrounding the outer edge of the opening 461c. The packing 464 is fitted into the recess 461e. An elastic material such as rubber is used for the packing 464. The packing 464 enters the recess 461e, is sandwiched between the flow path 461 and the irradiation window 463, and is slightly elastically deformed to close the gap between the flow path 461 and the irradiation window 463. As a result, the packing 464 suppresses water leakage from the irradiation window 463.

Further, a lid portion 465 is attached to one end of the flow path 461. The lid portion 465 is attached to one end of the flow path 461 and sandwiches the irradiation window 463 and the packing 464 together with the flow path 461. As a result, the lid portion 465 holds the irradiation window 463 and the packing 464. The lid portion 465 is provided with an opening 465a at a position facing the irradiation window 463.

The light emitting element 462 is mounted on the substrate 466. The substrate 466 is attached to the lid 465 from the side opposite to the flow path 461. The light emitting element 462 enters the opening 465a of the lid portion 465 with the substrate 466 attached to the lid portion 465. As a result, the light emitting element 462 faces the irradiation window 463, and the ultraviolet rays emitted from the light emitting element 462 enter the flow path 461 through the irradiation window 463. The light emitting element 462 is connected to the control unit 405 via, for example, the substrate 466, and irradiates ultraviolet rays in response to an instruction from the control unit 405. The lighting and extinguishing of the light emitting element 462 is controlled by the control unit 405.

In this way, the irradiation window 463 and the light emitting element 462 are attached to one end of the tubular flow path 461. Therefore, the direction in which the light emitting element 462 is irradiated with ultraviolet rays is the same as the direction in which the flow path 461 extends. For example, the optical axis of the light emitting element 462 is substantially parallel to the extending direction of the flow path 461. The light emitting element 462 irradiates ultraviolet rays in a direction parallel to the direction of water flowing in the flow path 461. The ultraviolet irradiation direction of the light emitting element 462 does not have to be exactly parallel to the direction of the water flowing in the flow path 461, and has a component at least parallel to the direction of the water flowing in the flow path 461. I just need to be there.

The irradiation direction of the ultraviolet rays of the light emitting element 462 is not limited to the above, and may be any direction in which the ultraviolet rays can be irradiated to the water flowing through the flow path 461. However, as described above, by making the direction of irradiating the ultraviolet rays of the light emitting element 462 parallel to the direction of the water flowing in the flow path 461, the time for the ultraviolet rays to hit the water becomes longer, and the bacteria contained in the water are more likely to be exposed. It can be reduced appropriately.

In this example, a straight tubular flow path 461 is shown. For example, a straight tubular portion is provided in at least a part of the flow path 461, and the extending direction of the straight tubular portion is irradiation of ultraviolet rays of the light emitting element 462. It may be the same as the direction.

The flow path 461 has a main body portion 467 and a reflection portion 468. The reflection portion 468 is provided inside the main body portion 467. The reflective portion 468 forms at least a part of the inner surface of the flow path 461. The reflecting unit 468 is reflective to the ultraviolet rays emitted from the light emitting element 462. The reflectance of the reflecting portion 468 is higher than that of the main body portion 467 with respect to the ultraviolet rays emitted from the light emitting element 462. For the main body 467, for example, a resin material is used. For the reflective portion 468, for example, a metal material such as aluminum, stainless steel, or silver is used. The material of the reflective portion 468 is not limited to the metal material, and may be, for example, a dielectric multilayer film or the like. The material of the reflecting portion 468 may be any material that is reflective to the ultraviolet rays emitted from the light emitting element 462 and has a higher reflectance than the main body portion 467.

The flow path 461 is arranged in the casing 400 with the opening 461b facing upward. The irradiation window 463 and the light emitting element 462 are arranged below the flow path 461 in the vertical direction. In other words, the irradiation window 463 and the light emitting element 462 are provided at the lower end of the flow path 461 extending in the vertical direction. As described above, the irradiation window 463 and the light emitting element 462 are arranged so that the irradiation direction of the ultraviolet rays faces upward in the installed state in the casing 400.

When the flow path 461 is arranged as described above and water flows from the opening 461a toward the opening 461b, the direction of water flow in the flow path 461 is upward. Further, in this case, the direction of the ultraviolet rays emitted from the light emitting element 462 is the same as the direction of the water flowing in the flow path 461.

On the contrary, when water flows from the opening 461b toward the opening 461a, the direction of the water flowing in the flow path 461 is downward, and the direction of the ultraviolet rays emitted from the light emitting element 462 is the direction of the water flowing in the flow path 461. The direction is opposite to that of. As described above, the direction of the ultraviolet rays emitted from the light emitting element 462 may be the same as or opposite to the direction of the water flowing in the flow path 461.

Next, a specific example of the operation of the sanitary cleaning device according to the present embodiment will be described with reference to the drawings.
FIG. 4 is a timing chart illustrating a specific example of the operation of the sanitary cleaning device according to the present embodiment.
As shown in FIG. 4, the nozzle 473 is housed in the casing 400 in the standby state before the seating detection sensor 404 detects the user (timing t0 to t1).

When the human body detection sensor 403 detects a user who has entered the toilet room, the control unit 405 opens the solenoid valve 431 and the flow path switching unit 472 so that only the spray nozzle 479 communicates with the pipeline 20a of the water guide unit 20. The clean water is sprayed onto the surface of the bowl 801 by driving (timing t1). The time for spraying the clean water is, for example, about 4 seconds (timing t1 to t2). In this way, by wetting the surface of the bowl 801 before the user uses the toilet bowl 800, the filth adhering to the surface of the bowl 801 can be reduced.

When the control unit 405 receives an instruction for cleaning the human body from the operation unit 500 in response to the operation of the user, the control unit 405 opens the solenoid valve 431 and transfers only the bidet cleaning spout 474a and the buttocks cleaning spout 474b to the water guiding unit 20. The flow path switching unit 472 is driven so as to communicate with the pipeline 20a (timing t3). As a result, the control unit 405 cleans the path from the water supply source 10 to the bidet washing spout 474a and the buttocks washing spout 474b with the nozzle 473 housed.

Further, the control unit 405 starts the generation of hot water by operating the heat exchanger unit 440 at this timing, lights the light emitting element 462 of the ultraviolet irradiation unit 460, and emits ultraviolet rays to the water flowing in the flow path 461. Start irradiation. As a result, bacteria contained in the water flowing through the flow path 461 can be reduced, and safe cleaning water can be supplied to the nozzle 473.

After cleaning for a predetermined time, the control unit 405 drives the flow path switching unit 472 so that only the nozzle cleaning chamber 478 communicates with the pipeline 20a of the water guide unit 20, and drives the nozzle motor 476. The nozzle 473 is advanced into the bowl 801 while cleaning the body of the nozzle 473 (timing t4).

After advancing the nozzle 473 into the bowl, the control unit 405 has a flow path switching unit 472 so that only one of the bidet cleaning spout 474a and the buttocks cleaning spout 474b communicates with the pipe line 20a of the water guiding unit 20. Is driven to start washing the human body (timing t5).

When the operation unit 500 instructs the control unit 405 to stop cleaning the human body, the control unit 405 drives the flow path switching unit 472 so that only the nozzle cleaning chamber 478 communicates with the conduit 20a of the water guide unit 20, and the nozzle motor 476. The nozzle 473 is housed in the casing 400 while cleaning the body of the nozzle 473 (timing t6).

After completing the storage of the nozzle 473, the control unit 405 drives the flow path switching unit 472 so that only the bidet cleaning spout 474a and the buttocks cleaning spout 474b communicate with the pipeline 20a of the water guiding unit 20. , The path from the water supply source 10 to the nozzle 473 is washed (timing t7).

After cleaning for a predetermined time, the control unit 405 closes the solenoid valve 431 and stops the operations of the heat exchanger unit 440 and the ultraviolet irradiation unit 460 (timing t8).

The control unit 405 connects the bidet cleaning spout 474a, the tail cleaning spout 474b, the nozzle cleaning chamber 478, and the spray nozzle 479 to the pipeline 20a after a predetermined time has elapsed from the release of the user's detection by the human body detection sensor 403. By driving the flow path switching unit 472 so as to communicate with the nozzle 473, the water accumulated in the nozzle 473 is drained (timing t9). At this time, when the amount of water in the vacuum breaker 452 decreases, the intake port of the vacuum breaker 452 opens, and air is taken into the pipe line 20a. As a result, drainage of the portion downstream of the vacuum breaker 452 is promoted.

After draining water for a predetermined time, the control unit 405 drives the flow path switching unit 472 to drive the bidet cleaning spout 474a, the buttocks cleaning spout 474b, the nozzle cleaning chamber 478, and the spray nozzle 479, and the pipeline 20a. Close the communication with (timing t10).

The control unit 405 opens the solenoid valve 431 after a further predetermined time has elapsed from the water draining operation, and communicates only the bidet cleaning spout 474a and the buttocks cleaning spout 474b to the pipeline 20a of the water guiding unit 20. The switching unit 472 is driven (timing t11). Further, the control unit 405 operates the electrolytic cell unit 450. As a result, the control unit 405 cleans the path from the water supply source 10 to the bidet washing spout 474a and the buttocks washing spout 474b with the functional water while the nozzle 473 is housed. The control unit 405 sterilizes the path between the electrolytic cell unit 450 and the nozzle 473 with functional water, for example.

After cleaning for a predetermined time, the control unit 405 drives the flow path switching unit 472 so that only the nozzle cleaning chamber 478 communicates with the pipeline 20a of the water guide unit 20, and drives the nozzle motor 476. The nozzle 473 is moved forward and backward, and the body of the nozzle 473 is washed with functional water (timing t11 to t12). For example, the body of nozzle 473 is sterilized with functional water.

After cleaning the body of the nozzle 473, the control unit 405 cleans the path between the electrolytic cell unit 450 and the nozzle 473 again with functional water, closes the solenoid valve 431, and stops the operation of the electrolytic cell unit 450. (Timing t13 to t14).

After sterilizing the nozzle 473, the control unit 405 performs a water draining operation again (timing t15). At this time, the control unit 405 drives the nozzle motor 476 to move the nozzle 473 forward and backward (timing t16 to t17). As a result, for example, the height difference between the vacuum breaker 452 and the spouts 474a and 474b becomes large, and drainage of a portion downstream of the vacuum breaker 452 can be performed more reliably.

As described above, in the sanitary cleaning device 100, the ultraviolet irradiation unit 460 is arranged on the upstream side of the vacuum breaker 452. The portion of the pipeline 20a on the upstream side of the vacuum breaker 452 is not drained. Therefore, in the sanitary cleaning device 100, even if water escapes in the water guide portion 20 on the downstream side of the vacuum breaker 452, the water in the flow path 461 of the ultraviolet irradiation unit 460 is suppressed from flowing out, and water enters the flow path 461. Can be made to stay. Even after the water draining operation is performed, the flow path 461 can be filled with water. As a result, it is possible to prevent the water from drying on the surface of the irradiation window 463 and to prevent water stains from depositing on the irradiation window 463. Therefore, the deterioration of the effect of reducing the bacteria of the ultraviolet irradiation unit 460 can be suppressed. It is possible to suppress the deterioration of the performance of the ultraviolet irradiation unit 460 due to the generation of water stains.

Further, in the sanitary cleaning device 100, the ultraviolet irradiation unit 460 is arranged on the upstream side of the heat exchanger unit 440. The generation of scale is temperature dependent. As the water temperature rises, the amount of calcium carbonate dissolved decreases. That is, when the water temperature rises, calcium carbonate becomes difficult to dissolve in water. Therefore, when the water temperature rises, scales are likely to be generated and precipitated as scale. Therefore, the higher the temperature of the water flowing in the flow path 461, the more easily scale is generated in the flow path 461.

In the sanitary cleaning device 100, since the ultraviolet irradiation unit 460 is arranged upstream of the heat exchanger unit 440, the water supplied to the ultraviolet irradiation unit 460 is cold water supplied from the water supply source 10. As a result, the generation of scale in the flow path 461 can be suppressed as compared with the case where the hot water generated by the heat exchanger unit 440 is supplied to the ultraviolet irradiation unit 460. Therefore, as compared with the case where hot water is supplied, it is possible to further suppress the deterioration of the performance of the ultraviolet irradiation unit 460 due to the precipitation of water stains on the surface of the irradiation window 463.

Further, in the sanitary cleaning device 100, an irradiation window 463 and a light emitting element 462 are provided at the lower end of the flow path 461 extending in the vertical direction, and the irradiation window is provided so that the irradiation direction of ultraviolet rays faces upward in the installed state in the casing 400. 463 and a light emitting element 462 are arranged. As a result, even when the water in the flow path 461 begins to dry (evaporate) due to non-use for a long time, the water stays on the irradiation window 463 until the end, and the water on the surface of the irradiation window 463. Can be prevented from drying out. Therefore, the deterioration of the effect of reducing the bacteria of the ultraviolet irradiation unit 460 can be further suppressed.

Further, in the sanitary cleaning device 100, since the irradiation direction of the ultraviolet rays of the light emitting element 462 is parallel to the direction of the water flowing in the flow path 461, the time during which the ultraviolet rays are exposed to the water can be lengthened more reliably. Bacteria can be reduced.

Further, in the sanitary cleaning device 100, the ultraviolet irradiation unit 460 is arranged on the downstream side of the pressure regulating valve 432. As a result, it is possible to prevent the relatively high pressure water supplied from the water supply source 10 from being directly supplied to the ultraviolet irradiation unit 460. For example, it is possible to suppress damage to the ultraviolet irradiation unit 460 and further improve the reliability of the sanitary cleaning device 100.

Further, in the sanitary cleaning device 100, since the reflection unit 468 is provided in the flow path 461 of the ultraviolet irradiation unit 460, it is possible to easily reflect the ultraviolet rays in the flow path 461. It is possible to suppress the absorption of light on the inner surface of the flow path 461. For example, light can be distributed to the details of the flow path 461, and bacteria contained in water can be efficiently reduced.

5 (a) and 5 (b) are cross-sectional views showing a modified example of the ultraviolet irradiation portion according to the present embodiment.
As shown in FIG. 5A, the flow path 461 may be arranged in the casing 400 with the opening 461b facing diagonally upward. The irradiation window 463 and the light emitting element 462 may be provided at the lower end of the flow path 461 extending in a direction inclined with respect to the vertical direction, and may be arranged so that the ultraviolet irradiation direction faces diagonally upward in the installed state in the casing 400. Good.

As described above, the irradiation window 463 and the light emitting element 462 may be arranged so as to have a component in which the irradiation direction of ultraviolet rays is at least upward in the installed state in the casing 400. As a result, as described above, even when the water in the flow path 461 begins to dry due to non-use for a long time, the water stays on the irradiation window 463 until the relatively end, and the surface of the irradiation window 463. It is possible to prevent the water from drying out.

As shown in FIG. 5B, the flow path 461 may be arranged in the casing 400 with the opening 461b oriented horizontally. The irradiation window 463 and the light emitting element 462 may be provided at one end of the flow path 461 extending in the horizontal direction, and may be arranged so that the irradiation direction of ultraviolet rays faces the horizontal direction in the installed state in the casing 400.

In this way, even when the irradiation window 463 and the light emitting element 462 are arranged so as to irradiate the ultraviolet rays in the horizontal direction, for example, the irradiation window 463 and the light emitting element 462 are provided above the flow path 461 and the ultraviolet rays are directed downward. It is possible to suppress the drying of water on the surface of the irradiation window 463 as compared with the case of irradiating.

As described above, the irradiation window 463 and the light emitting element 462 may be arranged so that the irradiation direction of ultraviolet rays is at least horizontal or upward in the installed state in the casing 400. As a result, it is possible to suppress the drying of water on the surface of the irradiation window 463, and further suppress the deterioration of the performance of the ultraviolet irradiation unit 460 due to the precipitation of water stains.

6 (a) and 6 (b) are cross-sectional views showing a modified example of the ultraviolet irradiation portion according to the present embodiment.
As shown in FIG. 6A, the ultraviolet irradiation unit 600 has a flow path 601 and a light emitting element 602 (light emitting unit). The flow path 601 is, for example, cylindrical. The flow path 601 may have another tubular shape such as a square tubular shape. Openings 601a and 601b are provided at both ends of the flow path 601 respectively. The flow path 601 supplies water from one of the openings 601a and 601b and discharges water from the other of the openings 601a and 601b, so that the water flows along the extending direction of the flow path 601.

An irradiation window 603 is provided on the side surface of the flow path 601. The light emitting element 602 is provided on the outside of the flow path 601 facing the irradiation window 603, so that the water flowing in the flow path 601 through the irradiation window 603 is irradiated with ultraviolet rays. In this example, the light emitting element 602 causes ultraviolet rays to enter the flow path 601 from the irradiation window 603 provided on the side surface of the flow path 601 so that the ultraviolet rays intersect with the direction of the water flowing in the flow path 601. Irradiate.

The light emitting element 602 irradiates, for example, ultraviolet rays substantially perpendicular to the water flowing in the flow path 601. The irradiation direction of the ultraviolet rays of the light emitting element 602 is not limited to a direction substantially perpendicular to the water flowing in the flow path 601 and may be inclined with respect to the water flowing in the flow path 601. The irradiation direction of the ultraviolet rays of the light emitting element 602 may be any direction that intersects with the direction of the water flowing in the flow path 601. Since the functions and materials of the light emitting element 602 and the irradiation window 603 are substantially the same as those of the light emitting element 462 and the irradiation window 463 of the above embodiment, detailed description thereof will be omitted.

The ultraviolet irradiation unit 600 further includes, for example, a lid unit 604 and a substrate 605. The lid portion 604 is provided on the side surface of the flow path 601 and covers the outer edge of the irradiation window 603 from the outside of the flow path 601 to suppress water leakage from the opening provided with the irradiation window 603 in the flow path 601. ..

The substrate 605 is attached to the lid portion 604 from the side opposite to the flow path 601. The light emitting element 602 is mounted on the substrate 605. The light emitting element 602 enters the opening of the lid portion 604 with the substrate 605 attached to the lid portion 604. As a result, the light emitting element 602 faces the irradiation window 603, and the ultraviolet rays emitted from the light emitting element 602 enter the flow path 601 through the irradiation window 603. The light emitting element 602 is connected to the control unit 405 via the substrate 605, for example, and irradiates ultraviolet rays in response to an instruction from the control unit 405. The lighting and extinguishing of the light emitting element 602 is controlled by the control unit 405.

The irradiation window 603 and the light emitting element 602 are arranged below the flow path 601 in the vertical direction in the installed state in the casing 400. The flow path 601 is arranged substantially horizontally, for example, and the light emitting element 602 is arranged below the flow path 601 to irradiate ultraviolet rays upward.

As a result, as in the above embodiment, even when the water in the flow path 601 begins to dry due to non-use for a long time, the water is allowed to stay on the irradiation window 603 until the relatively end, and the irradiation window 603 It is possible to prevent the water from drying on the surface of the window. Therefore, the deterioration of the effect of reducing the bacteria of the ultraviolet irradiation unit 600 can be further suppressed.

As shown in FIG. 6B, the flow path 601 may be arranged in the casing 400 in a state of being inclined with respect to the vertical direction and the horizontal direction. When irradiating ultraviolet rays in a direction intersecting the direction of water flowing in the flow path 601, it is preferable to arrange the flow path 601 substantially horizontally or at an angle with respect to the vertical direction and the horizontal direction. .. In other words, when irradiating ultraviolet rays in a direction intersecting the direction of water flowing in the flow path 601, it is preferable not to arrange them in parallel with the vertical direction. The flow path 601 is arranged as described above, and the irradiation window 603 and the light emitting element 602 are arranged below the flow path 601. That is, the ultraviolet irradiation direction should not be the horizontal direction. As a result, it is possible to suppress the drying of the water on the surface of the irradiation window 603 when the water in the flow path 601 starts to dry.

7 (a) and 7 (b) are cross-sectional views showing a modified example of the ultraviolet irradiation portion according to the present embodiment.
As shown in FIG. 7A, the ultraviolet irradiation unit 610 has a flow path 611 and a cold cathode tube 612 (light emitting unit). The flow path 611 allows water to flow inside. The cold cathode fluorescent lamp (CCFL: Cold Cathode Fluorescent Lamp) 612 irradiates the water flowing through the flow path 611 with ultraviolet rays. The cold-cathode tube 612 extends in one direction. The cold cathode tube 612 is, for example, a columnar straight tube. The cold cathode tube 612 is inserted into the flow path 611. The flow path 611 is formed along the longitudinal direction of the cold cathode tube 612 (the direction in which the cold cathode tube 612 extends), and the flow path 611 allows water to flow along the longitudinal direction of the cold cathode tube 612.

The cold cathode tube 612 has a glass tube 612a for sealing a gas or the like. The cold cathode tube 612 irradiates the water flowing through the flow path 611 via the glass tube 612a with ultraviolet rays. In this way, when the cold cathode tube 612 is inserted into the flow path 611, the glass tube 612a of the cold cathode tube 612 itself may be used as the irradiation window.

The flow path 611 has a main body portion 611a extending in the longitudinal direction of the cold cathode tube 612. The cold cathode tube 612 is inserted through the main body 611a. An opening 611b is provided at one end of the flow path 611. An opening 611c is provided at the other end of the flow path 611. The openings 611b and 611c face in a direction substantially orthogonal to the extending direction of the main body 611a. That is, in this example, the flow path 611 is a pipeline having a substantially U-shaped cross section. The shape of the flow path 611 is not limited to this, and may be any shape along the longitudinal direction of the cold cathode tube 612.

For the flow path 611, for example, it is preferable to use a material that is reflective to ultraviolet rays emitted from the cold cathode tube 612, such as a metal material. The flow path 611 may have a reflective portion and a less reflective portion using a resin material or the like, for example, as in the main body portion 467 and the reflective portion 468 described with respect to the above embodiment. For example, a base material using a resin material may be subjected to a surface treatment such as a plating treatment to have reflectivity against ultraviolet rays.

As shown in FIG. 7B, the ultraviolet irradiation unit 620 has a flow path 621, a cold cathode tube 622 (light emitting unit), and an irradiation window 623. The cold cathode tube 622 is a straight tube as described above. The flow path 621 is a pipeline having a substantially U-shaped cross section having a main body portion 621a extending in the longitudinal direction and a pair of openings 621b and 621c. Further, the main body portion 621a of the flow path 621 is provided with an opening 621d along the longitudinal direction.

The irradiation window 623 closes the opening 621d of the flow path 621. The irradiation window 623 is transparent to the ultraviolet rays emitted from the cold cathode tube 622. The cold-cathode tube 622 faces the main body 621a of the flow path 621 with the irradiation window 623 interposed therebetween. As a result, the cold-cathode tube 622 irradiates the water flowing through the flow path 621 through the irradiation window 623 with ultraviolet rays.

As described above, the cold cathode tube 622 may be provided outside the flow path 621. In this case, the irradiation window 623 closes the opening 621d of the flow path 621, and ultraviolet rays are incident into the flow path 621 through the irradiation window 623. For example, the opening 621d may be closed with the glass tube 622a of the cold cathode tube 622, and the ultraviolet rays may be incident into the flow path 621 using the glass tube 622a as an irradiation window. For example, a part of the flow path 621 may be used as an irradiation window by forming the flow path 621 itself with a material transparent to ultraviolet rays such as quartz glass.

The ultraviolet irradiation unit 620 further includes a reflective material 624. The reflective material 624 faces the irradiation window 623 with the cold cathode tube 622 interposed therebetween. The reflective material 624 is reflective to the ultraviolet rays emitted from the cold cathode tube 622. The reflector 624 reflects the ultraviolet rays emitted from the cold cathode tube 622 toward the side opposite to the flow path 621 and directs the ultraviolet rays toward the flow path 621. As a result, the utilization efficiency of the ultraviolet rays emitted from the cold cathode tube 622 can be improved. The reflective material 624 is provided as needed and can be omitted.

As described above, the light emitting unit that irradiates the water flowing in the flow path with ultraviolet rays is not limited to the light emitting element, and may be, for example, a mercury lamp such as a cold cathode tube. The mercury lamp is, for example, a high-pressure mercury lamp or a low-pressure mercury lamp. The high-pressure mercury lamp is, for example, a metal halide lamp or the like. The low-pressure mercury lamp is, for example, a cold cathode tube or a hot cathode tube. When a mercury lamp is used for the light emitting portion, the mercury lamp may be inserted into the flow path or may be irradiated with ultraviolet rays into the flow path through the irradiation window. When a mercury lamp extending in the longitudinal direction is used, the flow path is formed along the longitudinal direction. This makes it possible to prolong the time that the ultraviolet rays are exposed to the water flowing through the flow path, for example. For example, the ultraviolet rays emitted from the mercury lamp can be efficiently incident on the water flowing through the flow path. As a result, when a mercury lamp is used for the light emitting portion, bacteria can be reduced more reliably.

In the above embodiment, an integrated toilet device in which the sanitary cleaning device 100 and the toilet bowl 800 are integrated is illustrated. The sanitary cleaning device may be, for example, a so-called seat type toilet seat device that is detachably attached to the toilet bowl.

The embodiments of the present invention have been described above. However, the present invention is not limited to these descriptions. With respect to the above-described embodiment, those skilled in the art with appropriate design changes are also included in the scope of the present invention as long as they have the features of the present invention. For example, the shape, size, material, arrangement, installation form, and the like of each element included in the sanitary cleaning device 100 and the like are not limited to those illustrated, and can be changed as appropriate.
In addition, the elements included in each of the above-described embodiments can be combined as much as technically possible, and the combination thereof is also included in the scope of the present invention as long as the features of the present invention are included.

10 water supply source, 20 water guide, 21 tail cleaning channel, 22 soft cleaning channel, 23 bidet cleaning channel, 24 surface cleaning channel, 25 spraying channel, 100 sanitary cleaning device, 200 toilet seat, 300 toilet lid, 310 transmission window, 400 casing, 401 power supply circuit, 403 human body detection sensor, 404 seating detection sensor, 405 control unit, 407 exhaust port, 408 outlet port, 409 recessed part, 431 electromagnetic valve, 432 pressure control valve, 433 check valve , 434 constant flow valve, 440 heat exchanger unit, 442 flow sensor, 450 electrolytic tank unit, 452 vacuum breaker, 454 pressure modulator, 460 ultraviolet irradiation unit, 461 flow path, 462 light emitting element, 463 irradiation window, 464 packing, 465 lid, 466 board, 467 main body, 468 reflector, 471 flow adjustment, 472 flow path switching, 473 nozzle, 474a bidet cleaning spout, 474b toilet cleaning spout, 476 nozzle motor, 478 nozzle cleaning chamber, 479 spray nozzle, 500 operation unit, 600, 610, 620 ultraviolet irradiation unit, 601, 611, 621 flow path, 602 light emitting element, 603 irradiation window, 604 lid, 605 substrate, 612, 622 cold cathode tube, 623 irradiation window , 624 Reflective material, 800 toilet bowl, 801 bowl

Claims (4)

A nozzle that discharges water toward the local part of the human body,
A water guide that has a pipeline from the water supply source to the nozzle and guides the water supplied from the water supply source to the nozzle.
A vacuum breaker provided on the path of the water guide and taking in air into the pipe when there is no water flow in the water guide.
Ultraviolet irradiation having a flow path provided on the path of the water conveyance section on the upstream side of the vacuum breaker and flowing water, and a light emitting section for irradiating the water flowing in the flow path through the irradiation window with ultraviolet rays. Department and
A sanitary cleaning device characterized by being equipped with. The sanitary cleaning apparatus according to claim 1, further comprising a heating unit for heating water, which is provided on the path of the water guide unit on the downstream side of the ultraviolet irradiation unit . The flow path is tubular and has a tubular shape.
The irradiation window is provided on the side surface of the flow path.
The light emitting unit irradiates the ultraviolet rays in a direction intersecting the direction of water flowing in the flow path.
The sanitary cleaning device according to claim 1 or 2, wherein the irradiation window and the light emitting unit are arranged below the flow path in the vertical direction in an installed state. The flow path is tubular and has a tubular shape.
The irradiation window is provided at one end of the flow path and is provided.
The light emitting unit irradiates the ultraviolet rays in a direction parallel to the direction of water flowing in the flow path.
The sanitary cleaning device according to claim 1 or 2, wherein the irradiation window and the light emitting unit are arranged so that the irradiation direction of the ultraviolet rays faces horizontally or upward in the installed state.

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