JP7236053B2 - toilet seat device - Google Patents

Description

Aspects of the present invention generally relate to toilet seat devices.

A toilet seat device that suppresses the growth of bacteria and stains in the bowl by spouting cleaning water (disinfecting water) such as hypochlorous acid water, which has oxidative decomposition and bleaching effects, into the bowl. known (for example, Patent Document 1). In addition, ozonated water, electrolytically sterilized water, and high-temperature water are made into a mist of about 0.1 to 50 μm, and this mist is delivered not only to the bowl but also to the toilet seat, toilet lid, and toilet rim by air currents. There is known a toilet seat device with mist cleaning that cleans every corner of the toilet seat (for example, Patent Document 2).

Japanese Patent No. 5029930 Japanese Patent Application Laid-Open No. 2007-138605

By spraying the mist (cleansing water) onto the toilet bowl and the toilet seat, the cleanliness of the toilet seat device can be maintained. Such mist spraying is performed, for example, after using the toilet. However, if the user sits on the toilet seat immediately after the mist is sprayed on the toilet seat, the user's buttocks may get wet and the user may feel uncomfortable. On the other hand, if the mist is prevented from landing on the toilet seat surface (seating surface) of the toilet seat, there is a problem that the toilet seat surface cannot be disinfected.

SUMMARY OF THE INVENTION The present invention has been made based on the recognition of such problems, and an object of the present invention is to provide a toilet seat device capable of efficiently causing mist to land on the toilet seat front surface and the toilet seat back surface.

A first invention is a toilet seat portion having a toilet seat surface on which a user sits, a toilet seat back located on the back side of the toilet seat surface, and an opening penetrating between the toilet seat surface and the toilet seat back; a spraying device that sprays a user, a detection sensor that detects a user, and a control device that controls the spraying device based on detection information of the detection sensor, wherein the control device is configured such that the detection sensor detects the user an after-mist mode that is executed when the user is not detected from the state of detection, and in which the mist is prevented from landing on the surface of the toilet seat and the mist lands on the back surface of the toilet seat; and a regular mist mode in which the detection sensor does not detect the user and is executed at a predetermined timing to cause the mist to land on the surface of the toilet seat.

According to this toilet seat device, the after-mist mode makes it possible to clean the back surface of the toilet seat (bleaching of stains and sterilization of bacteria) by causing mist to land on the back surface of the toilet seat with a large dirt load. In addition, by suppressing the mist from landing on the toilet seat surface with a small dirt load, it is possible to suppress the user's buttocks from getting wet even when the user sits on the toilet seat immediately after the after-mist mode. In addition, by spraying mist onto the surface of the toilet seat in the regular mist mode, it is possible to disinfect the surface of the toilet seat that could not be disinfected in the after-mist mode. Note that the regular mist mode is executed at a predetermined timing, for example, during non-use hours when the toilet seat device is not used for a long period of time. This can reduce the possibility of the user's buttocks getting wet. Therefore, by executing the after-mist mode and the regular mist mode in combination, it is possible to provide a toilet seat device that is both clean and easy to use.

A second invention is a toilet seat portion having a toilet seat surface on which a user sits, a toilet seat back surface located behind the toilet seat surface, and an opening penetrating between the toilet seat surface and the toilet seat back surface, and a mist a spraying device that sprays a user, a detection sensor that detects a user, and a control device that controls the spraying device based on detection information of the detection sensor, wherein the control device is configured such that the detection sensor detects the user an after-mist mode, which is executed when the user is not detected from the detected state, and causes the mist to land on the toilet seat surface and the toilet seat back surface; and when the detection sensor detects the user. and a regular mist mode that is executed at a predetermined timing and causes the mist to land on the toilet seat surface, and the amount of the mist that lands on the toilet seat surface in the after-mist mode is The toilet seat device is characterized in that the amount of the mist that lands on the surface of the toilet seat is less than that of the mist that lands on the surface of the toilet seat in the regular mist mode.

According to this toilet seat device, the after-mist mode makes it possible to clean the back surface of the toilet seat (bleaching of stains and sterilization of bacteria) by causing mist to land on the back surface of the toilet seat with a large dirt load. In addition, by reducing the amount of water mist that lands on the toilet seat surface with a small dirt load, the mist on the toilet seat surface can be dried quickly. can also prevent the user's buttocks from getting wet. In addition, the periodic mist mode allows a large amount of mist to land on the surface of the toilet seat, making it possible to clean the surface of the toilet seat that could not be sufficiently cleaned in the after-mist mode. Note that the regular mist mode is executed at a predetermined timing, for example, during non-use hours when the toilet seat device is not used for a long period of time. This can reduce the possibility of the user's buttocks getting wet.

According to a third aspect of the present invention, there is provided an air blower for generating an air current inside the toilet bowl by blowing air toward the inside of the toilet bowl in the first or second invention, and the spray device is positioned below the toilet seat portion. , wherein the air blower generates an upward air current that causes the mist sprayed from the spray device to rise from the inside of the toilet bowl toward the opening of the toilet seat, and the control device generates the upward air current The toilet seat apparatus is characterized in that the air blower is controlled so that the air blower is smaller in the after-mist mode than in the regular mist mode.

According to this toilet seat device, mist can be delivered to the toilet seat from the spray device arranged below the toilet seat by using the air current (updraft). In addition, by changing the size of the rising air current, a single spray device and air blower can be used to create an after-mist mode, in which mist lands on the back of the toilet seat so as not to over-wet the surface of the toilet seat. It can be switched between regular mist mode and watering mode.

In a fourth aspect based on the third aspect, the blower device has an air direction changing unit that changes the blowing direction of the airflow, and the control device changes the blowing direction of the airflow to the above airflow direction rather than the aftermist mode. The toilet seat device is characterized in that the airflow direction changer is controlled so that the regular mist mode is directed downward.

According to this toilet seat device, by setting the direction of the airflow downward in the regular mist mode, a large amount of airflow flows from the opening of the toilet seat toward the surface of the toilet seat, so that a large amount of mist lands on the surface of the toilet seat. can be made In addition, by making the airflow in after-mist mode more upward than in regular mist mode, a large amount of airflow flows between the back of the toilet seat and the upper surface of the rim of the toilet bowl, so more mist is deposited on the back of the toilet seat. can be watered. By executing the after-mist mode and the regular mist mode in this way, the mist can be effectively made to land on the toilet seat front surface and the toilet seat back surface.

In a fifth aspect based on the fourth aspect, the blower device has a blower portion that changes air volume, and the control device reduces the air volume in the regular mist mode rather than in the after mist mode. The toilet seat device is characterized in that the air blower is controlled as follows.

According to this toilet seat device, by reducing the air volume in the regular mist mode, the air current that collides (reflects) with the inner wall of the toilet bowl rises, so a large amount of air current can easily flow from the opening of the toilet seat toward the toilet seat surface. Become. As a result, in the regular mist mode, a large amount of mist can be made to land on the surface of the toilet seat. In addition, by setting the air volume in after-mist mode to be higher than that in regular mist mode, the airflow that collides with the inner wall of the toilet rises along the inner wall of the toilet, making it easier to flow between the back of the toilet seat and the upper surface of the rim of the toilet. Become. As a result, in the after-mist mode, a large amount of mist can land on the back of the toilet seat. By executing the after-mist mode and the regular mist mode in this way, the mist can be effectively made to land on the toilet seat front surface and the toilet seat back surface.

According to the aspect of the present invention, the mist can be efficiently landed on the toilet seat surface and the toilet seat back surface.

1 is a perspective view showing a toilet apparatus according to an embodiment of the present invention; FIG. FIG. 2 is a cross-sectional view of the toilet apparatus in FIG. 1 as viewed in the direction of arrows AA. FIG. 3 is a block diagram showing the essential configuration of the toilet seat device; 4(a) to 4(e) are a plan view and a perspective view showing the main body of the toilet seat device. It is a perspective view which shows the wind direction change part of an air blower. FIG. 5 is a cross-sectional view of the main body and the spray device in FIG. 4 is a flow chart showing control processing for an after-mist mode and a regular mist mode performed by a control device; FIGS. 8(a) and 8(b) are schematic diagrams showing the flow velocity state of the airflow in the after-mist mode. FIG. 4 is a schematic diagram schematically showing a state in which mist is placed on an airflow in a first turning direction in an after-mist mode; FIG. 7 is a schematic diagram schematically showing a state in which mist is placed on the airflow in the second turning direction in the after-mist mode; FIG. 4 is a schematic diagram schematically showing a state in which mist is placed on an airflow in a straight direction in an after-mist mode; FIGS. 12(a) and 12(b) are schematic diagrams showing the flow velocity state of the airflow in the regular mist mode. FIG. 5 is a schematic diagram schematically showing the relationship between airflow and mist when the mist lands on the right side of the toilet seat surface in the regular mist mode. FIG. 4 is a schematic diagram schematically showing the relationship between airflow and mist when the mist lands on the left side of the toilet seat surface in the regular mist mode. FIG. 4 is a schematic diagram schematically showing a state in which mist is placed on an airflow in a first turning direction in a regular mist mode; FIG. 10 is a schematic diagram schematically showing a state in which mist is placed on the airflow in the second turning direction in the regular mist mode; It is a schematic diagram which shows typically the state which carries mist on the airflow of a straight direction in regular mist mode. FIGS. 18(a) and 18(b) are schematic diagrams schematically showing modifications of the wind direction changing unit.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described with reference to the drawings. In addition, in each drawing, the same reference numerals are given to the same constituent elements, and detailed description thereof will be omitted as appropriate.
1 is a perspective view showing a toilet apparatus according to an embodiment of the present invention; FIG.
FIG. 2 is a cross-sectional view of the toilet apparatus in FIG. 1 as viewed in the direction of arrows AA.

A toilet device 1 shown in FIG. Toilet bowl 100 has a concave bowl portion 101 that receives waste. The toilet seat device 10 is installed on the upper part of the toilet bowl 100 .

The toilet seat device 10 includes a body portion 12 placed behind the toilet bowl 100, a toilet seat portion 14 rotatably supported by the body portion 12, and a spraying device 60 having a spraying portion 62 for spraying the mist M. , a seating detection sensor 20 and a human body detection sensor 22 for detecting the user, and a control device 70 for controlling the spray device 60 based on detection information from the seating detection sensor 20 and the human body detection sensor 22 . A toilet lid 16 rotatably supported on the main body 12 is provided on the rear side of the toilet seat 14 .

The toilet seat portion 14 has a toilet seat surface 14a on which a user sits, a toilet seat back surface 14b positioned behind the toilet seat surface 14a, and an opening 14c penetrating between the toilet seat surface 14a and the toilet seat back surface 14b. . The toilet seat surface 14a faces the toilet lid 16 when the toilet lid 16 is closed. The toilet seat back surface 14b faces the upper surface 103 of the rim portion 102 when the toilet seat portion 14 is closed (lowered). The opening 14c is located in the central portion of the toilet seat portion 14 and penetrates the bowl portion 101 . The state of FIG. 1 is a state in which the toilet seat 14 is closed and the toilet lid 16 is open (raised state). The toilet lid 16 covers the toilet seat surface 14a of the toilet seat portion 14 from above in the closed state.

The body portion 12 is provided with a seating detection sensor 20 for detecting that the user has sat on the toilet seat portion 14 . The seating detection sensor 20 constitutes the detection sensor of the present invention and outputs detection information to the control device 70 . Further, body washing function part 58 and the like are built in body part 12 to realize washing of the human body parts (such as "buttocks") of the user sitting on toilet seat part 14 . When the seat detection sensor 20 detects the user sitting on the toilet seat 14, when the user operates the manual operation unit 24 such as a remote controller, the washing nozzle of the body washing function unit 58 (hereinafter for convenience of explanation, simply referred to as “nozzle 58 a ”) can extend into bowl portion 101 of toilet 100 .

Note that the toilet seat device 10 shown in FIG. Further, inside the body portion 12, a blower device 31 and a spray device 60 are provided. The front wall 12a of the main body 12 is provided with an air blowing port 120 for blowing air from the air blower 31 toward the inside of the toilet bowl 100, and mist M sprayed from the spraying device 60 toward the inside of the toilet bowl 100. A discharge port 124 for discharging is provided so as to be spaced apart in the left-right direction.

One or a plurality of water outlets are provided at the tip of the nozzle 58a. The nozzle 58a jets water from a spout provided at its tip to wash the private parts (buttocks, etc.) of the user seated on the toilet seat 14 (toilet seat surface 14a). In the specification of the present application, the terms "upper", "lower", "forward", "backward", "left side", and "right side" respectively refer to the toilet seat portion 14 with the back facing the open toilet lid 16. This is the direction viewed from the user sitting on the

As shown in FIG. 2, the toilet bowl 100 has a rim portion 102 provided on the bowl portion 101 . Rim portion 102 is an annular portion that forms the upper edge of toilet bowl 100 . Rim portion 102 has an upper surface 103 and an inner wall surface 104 . The upper surface 103 faces the toilet seat back surface 14b of the closed toilet seat portion 14 .

The inner wall of the toilet bowl 100 (bowl portion 101) has an opening projection portion 101a. The opening projection portion 101a is a portion of the inner wall of the toilet bowl 100 in which the opening 14c of the toilet seat portion 14 is projected downward. As shown in FIG. 2, the opening projection portion 101a is positioned below the rim portion 102 of the inner wall of the toilet bowl 100. As shown in FIG. The opening projection part 101a has a bowl shape with a curved surface, and pooled water is stored below.

Then, for example, when the user performs a toilet cleaning operation using a switch provided on the manual operation unit 24 (remote controller), or when the user stands up from the toilet seat 14, the toilet is cleaned (the waste in the bowl 101 is discharged). and the operation of cleaning the surface of the bowl portion 101) is executed. Washing water is supplied into the bowl portion 101 in washing the toilet bowl.

FIG. 3 is a block diagram showing the essential configuration of the toilet seat device.
Note that FIG. 3 also shows the main configuration of the waterway system and the electrical system.
The seating detection sensor 20 can detect whether or not the user is seated on the toilet seat 14 . The seating detection sensor 20 detects seating and leaving of the user. The seating detection sensor 20 may be a microwave sensor, a ranging sensor (infrared projection sensor), an ultrasonic sensor, a tact switch, a capacitance switch (touch sensor), or a strain sensor.

When using contact sensors such as a tact switch, an electrostatic sensor, and a strain sensor, these contact sensors are provided on the toilet seat 14 . When the user sits on the toilet seat 14, the tact switch is pressed by the user's weight. Alternatively, the user touches the electrostatic sensor. Alternatively, pressure is applied to the strain sensor by the weight of the user. The seating of the user can be detected by electrical signals from these sensors.

The human body detection sensor 22 can detect a user in front of the toilet bowl 100 , that is, a user in a position spaced forward from the toilet seat 14 . That is, the human body detection sensor 22 can detect a user who has entered the toilet room and approaches the toilet seat 14 . The human body detection sensor 22 constitutes the detection sensor of the present invention and outputs detection information to the control device 70 . As such a human body detection sensor, for example, a pyroelectric sensor, a microwave sensor, an ultrasonic sensor, or a ranging sensor (infrared projection type sensor) can be used. The human body detection sensor 22 detects a user who has just opened the door of the toilet room and entered the room, or a user who has just entered the toilet room, that is, a user who is about to enter the toilet room and is present in front of the door. good too. For example, when a microwave sensor is used, it is possible to detect the presence of the user through the door of the toilet room.

The manual operation unit 24 is an operation unit for the user to spray the sterilizing water at any timing, for example. The manual operation unit 24 is a remote controller having switches, buttons, or the like. When the user operates the manual operation unit 24, operation information (signal) instructing spraying of the sterilizing water is sent to the control device 70. The control device 70 controls the sterilization device 54, the spray device 60, and the blower device 31 based on the operation information. Thereby, the user can spray the sterilized water by operating the manual operation unit 24 . In addition, the manual operation unit 24 may have switches, buttons, and the like for the user to operate each function of the toilet seat device 10 in addition to spraying the sterilized water. When an operation corresponding to each function is performed, the operation information is sent to the control device 70, and the control device 70 controls the operation of each part of the toilet seat device 10 based on the operation information.

In addition, a toilet seat motor 26 , a toilet lid motor 28 , a toilet seat heater 30 , an air blower 31 , a hot air heater 34 , and an air direction changing portion 36 are provided inside the body portion 12 . The toilet seat motor 26 electrically rotates and opens/closes the toilet seat 14 based on a command from the control device 70 . The toilet lid motor 28 electrically rotates the toilet lid 16 to open and close it based on a command from the control device 70 .

The toilet seat heater 30 is provided inside the toilet seat portion 14, for example. The toilet seat heater 30 has, for example, an annular metal member provided along the periphery of an opening 14c formed in the center of the toilet seat portion 14. As shown in FIG. The toilet seat heater 30 warms the toilet seat portion 14 by being energized based on a command from the control device 70 . As the toilet seat heater 30, for example, a tubing heater, a sheathed heater, a halogen heater, a carbon heater, or the like may be used. The metal member is made of, for example, aluminum or copper. Moreover, various shapes such as a sheet shape, a wire shape, and a mesh shape can be adopted as the shape of the metal member.

The air blower 31 generates an air current inside the toilet bowl 100 by blowing air toward the inside of the toilet bowl 100 . The air blower 31 generates an upward air current that lifts the mist M sprayed from the spray device 60 from the inside of the toilet bowl 100 toward the opening 14 c of the toilet seat 14 . The blower device 31 is provided inside the main body 12 and controlled by the control device 70 . The air blower 31 has an air blower 32 , a hot air heater 34 , and an air direction changer 36 .

The air blower 32 is, for example, a fan provided inside the main body 12 . Air blower 32 operates based on a command from control device 70 . The air blower 32 can blow air toward the inside of the toilet bowl 100 (inside the bowl portion 101) by, for example, rotating the blades as the motor rotates. The air blowing unit 32 carries the mist M ejected from the spray device 60 on the wind and sends the mist M to the toilet bowl 100 and the toilet seat portion 14 . The air blower 32 is an air volume changer that can change the air volume (air velocity) by controlling the rotation of a motor, for example.

In addition, when executing the local drying mode, the blower 31 blows air to the private parts of the user sitting on the toilet seat 14 to dry the private parts of the user. The hot air heater 34 warms the air that is sent to the outside of the main body 12 by the air blower 32 . As a result, warm air can be sent toward the user's private parts to dry the private parts.

The airflow direction changer 36 changes the direction of the airflow sent from the main body 12 toward the inside of the toilet bowl 100 . The wind direction changing unit 36 changes the airflow (wind direction) flowing through the toilet bowl 100 to cause the mist M ejected from the spray device 60 to land on the toilet bowl 100 and the toilet seat 14 at intended portions. Further, the airflow direction changing unit 36 directs the airflow direction toward the center of the toilet bowl 100 when drying the user's private parts. The wind direction changing unit 36 has a blowing damper 36a that changes the wind direction in the vertical direction, and a louver 36c that changes the wind direction in the horizontal direction. A specific configuration of the wind direction changing unit 36 will be described later.

In the water channel system, the toilet seat device 10 has pipes 40 to 43, an electromagnetic valve 50, a vacuum breaker 52, a sterilization device 54, a switching valve 56, a nozzle 58a, a nozzle cleaning chamber 58c, and a spray device 60. These are arranged within the body portion 12 .

The conduit 40 is for guiding water supplied from a water supply source (not shown) such as a tap or a water storage tank to the spray device 60, the nozzle 58a, and the like. A solenoid valve 50 is provided upstream of the pipeline 40 . The electromagnetic valve 50 is an electromagnetic valve that can be opened and closed, and controls water supply based on commands from a control device 70 provided inside the main body 12 .

A vacuum breaker 52 is provided downstream of the solenoid valve 50 on the pipeline 40 . The vacuum breaker 52 has, for example, a channel for flowing water, an intake port for taking air into the channel, and a valve mechanism for opening and closing the intake port. For example, the valve mechanism closes the intake port when water is flowing through the channel, and opens the intake port to take air into the channel when the flow of water stops. That is, vacuum breaker 52 draws in air when there is no water flow in line 40 . A float valve, for example, is used for the valve mechanism. The vacuum breaker 52 draws air into the pipeline 40 as described above, thereby facilitating draining of the downstream portion of the pipeline 40 from the vacuum breaker 52 , for example. Vacuum breaker 52 facilitates draining water from nozzle 58a and spray device 60, for example.

A sterilization device 54 that generates sterilized water is provided downstream of the vacuum breaker 52 on the pipeline 40 . The sterilization device 54 generates sterilized water containing, for example, hypochlorous acid. An example of the sterilization device 54 is an electrolytic cell unit. The electrolytic cell unit electrolyzes tap water flowing through a space (flow path) between an anode plate (not shown) and a cathode plate (not shown) under the control of energization from the control device 70 . Note that the sterilized water is not limited to one containing hypochlorous acid. The sterilized water may be, for example, a solution containing metal ions such as silver ions or copper ions, a solution containing electrolytic chlorine or ozone, acid water or alkaline water. The sterilization device 54 is not limited to an electrolytic cell, and may be of any configuration capable of generating sterilized water.

A switching valve 56 is provided downstream of the sterilization device 54 on the pipeline 40 . Downstream of the switching valve 56, the nozzle 58a of the body washing function unit 58, the nozzle washing chamber 58c, and the spray device 60 are provided. The pipeline 40 is branched by a switching valve 56 into a pipeline 41 that guides water to the nozzle 58 a , a pipeline 42 that guides water to the nozzle cleaning chamber 58 c , and a pipeline 43 that guides water to the spray device 60 . The switching valve 56 controls opening and closing of each of the pipelines 41 , 42 and 43 based on commands from the control device 70 . That is, the switching valve 56 controls the water supply to the nozzle 58a, the nozzle cleaning chamber 58c, and the spray device 60. FIG. Moreover, the switching valve 56 changes the flow rate of the water supplied downstream.

The body washing function part 58 has a nozzle 58a, a nozzle motor 58b, a nozzle washing chamber 58c, and a nozzle damper 58d. The nozzle 58a is housed in the main body 12 behind the nozzle damper 58d when not in use. When washing the human body private parts, the nozzle 58a receives a driving force from the nozzle motor 58b, presses the nozzle damper 58d that can be opened and closed with respect to the main body 12, and advances into the bowl portion 101 of the toilet bowl 100. . The nozzle motor 58b is driven based on a command from the control device 70. FIG. The nozzle 58a is extended forward from the main body 12 and discharges water from the spout to cleanse the human body. The nozzle cleaning chamber 58c cleans the outer peripheral surface (body) of the nozzle 58a by injecting sterilized water or tap water from a spout provided therein.

The spraying device 60 has a spraying part 62 that sprays the mist M onto at least one of the inside of the toilet bowl 100 (the bowl part 101 ) and the toilet seat part 14 . The spraying device 60 turns tap water or the sterilized water generated by the sterilizing device 54 into a mist, and the mist M is emitted from the spraying portion 62 through the discharge port 124 to the bowl portion 101, the rim portion 102, and the toilet seat portion. Spray to 14. In other words, the spray device 60 causes the sterile water mist M or tap water mist M to land on the bowl portion 101 , the rim portion 102 , and the toilet seat portion 14 . A specific configuration of the spray device 60 will be described later. In the specification of the present application, "landing on water" means that water (disinfected water or tap water) adheres to the surface of an object.

A circuit to which power is supplied from a power supply circuit (not shown) is used for the control device 70 . The control device 70 includes an integrated circuit such as a microcomputer. The control device 70 controls the toilet seat motor 26, the toilet lid motor 28, the toilet seat heater 30, and the air blower 30 based on detection information from the human body detection sensor 22 for detecting the user or the seating detection sensor 20 and operation information from the manual operation unit 24. It controls the device 31 , the solenoid valve 50 , the vacuum breaker 52 , the sterilization device 54 , the switching valve 56 , the nozzle motor 58 b and the spray device 60 .

The control device 70 receives detection information from the human body detection sensor 22 (signal indicating whether or not the user is present) and detection information from the seating detection sensor 20 (signal indicating whether or not the user is seated), and performs the received detection. Based on the information, the operation of each part of the toilet seat device 10 is controlled. Further, the control device 70 executes a local drying mode for drying the private parts (the buttocks, etc.) of the user sitting on the toilet seat 14 based on the operation information of the manual operation unit 24, for example. When executing the local drying mode, the control device 70 directs the blowing direction of the airflow to the central portion of the toilet bowl 100 by the louver 36c of the airflow direction changing portion 36. FIG.

The control device 70 controls the spray device 60 based on detection information from the human body detection sensor 22 . In this case, the control device 70 has an after-mist mode that is executed when the state in which the human body detection sensor 22 detects the user changes to a state in which the human body detection sensor 22 does not detect the user. and a regular mist mode that is not used and is executed at a predetermined timing. The user detection information is not limited to the human body detection sensor 22 and may be obtained by the seating detection sensor 20 .

The after-mist mode is an operation mode in which a mist M of sterilized water is automatically sprayed after the toilet device 1 is used by the user. In this after-mist mode, the mist M is caused to land on the toilet seat back surface 14b while suppressing the mist M from landing on the toilet seat surface 14a. That is, in the after-mist mode, the toilet bowl 100 with a large dirt load and the toilet seat back surface 14b are sterilized.

On the other hand, the periodic mist mode is an operation mode that automatically sprays the disinfected water mist M at a predetermined timing such as at night when the toilet device 1 is not used and the frequency of use of the toilet device 1 is low. . The predetermined timing at which the periodic mist mode is executed can be every predetermined time and at a predetermined time after the toilet seat apparatus 10 is powered on or after the after-mist mode. Also, the non-use time zone of the toilet seat device 10 may be learned and controlled, and the regular mist mode may be executed during the non-use time zone. The regular mist mode may be executed once a day, or may be executed multiple times. In this periodic mist mode, the mist M is caused to land on the toilet seat surface 14a in addition to the toilet bowl 100 and the toilet seat back surface 14b.

The amount of mist M that lands on the toilet seat surface 14a in the after-mist mode is smaller than the amount of water that lands on the toilet seat surface 14a in the regular mist mode. The control device 70 controls the blower device 31 and the spray device 60 to control the landing position of the mist M. Specific control of the after mist mode and the regular mist mode by the control device 70 will be described later.

Also, the control device 70 may have a pre-mist mode and a manual mist mode in addition to the after-mist mode and the regular mist mode. The pre-mist mode is an operation mode in which the mist M of sterilized water or tap water is automatically sprayed based on the detection information of the human body detection sensor 22 before the user uses the toilet device 1 . The manual mist mode is an operation mode for spraying mist M of sterile water based on the operation information of the manual operation unit 24 .

4(a) to 4(e) are a plan view and a perspective view showing the main body of the toilet seat device.
FIG. 5 is a perspective view showing a wind direction changing portion of the blower.
As shown in FIG. 4( a ), the spray device 60 , nozzle damper 58 d , and blower damper 36 a are positioned in the upper rear portion of the bowl portion 101 when the toilet seat device 10 is installed on the upper portion of the toilet bowl 100 . FIG.4(b) expands and shows a part of Fig.4 (a). In addition, in FIG. 4B, the front wall portion 122 of the main body portion 12 located in front of the spray device 60 is broken to show the storage chamber 121 in which the spray device 60 and the spray section 62 are accommodated. 4(c) to 4(e) are enlarged perspective views showing the surroundings of the spray device 60, the nozzle damper 58d, and the blower damper 36a.

The nozzle damper 58d is rotatably supported on the front wall 12a of the main body 12. As shown in FIG. Nozzle damper 58 d is located between outlet 124 and blower port 120 . The nozzle 58a is positioned behind the nozzle damper 58d in a state of being retracted inside the main body 12 . During washing of the human body private parts, the nozzle 58a abuts on the nozzle damper 58d, rotates the nozzle damper 58d to open, and advances from the inside of the main body 12. As shown in FIG.

The air blow damper 36a is located on the left side of the nozzle damper 58d and is rotatably supported on the front wall 12a of the main body 12. As shown in FIG. The blower damper 36 a constitutes a part of the wind direction changing section 36 . Behind the blower damper 36a, the blower section 32, the warm air heater 34, the louver 36c of the wind direction changing section 36, and the like are arranged.

The air blow damper 36 a covers the air blow port 120 of the main body 12 . That is, the blower port 120 is arranged on one side (left side) in the left-right direction of the nozzle 58a (nozzle damper 58d). The blower port 120 is located below the toilet seat surface 14 a and blows air from the blower 31 toward the inside of the toilet bowl 100 . That is, air blower port 120 is positioned between toilet 100 and toilet seat 14 on the rear side of toilet 100 . The air sent from the air blower 32 is sent into the toilet bowl 100 from the air blower 120 while the air direction is controlled by the air direction changer 36 .

FIG. 4(c) shows a state in which the blower device 31 has stopped operating, and FIGS. 4(d) and 4(e) show that the blower device 31 operates and blows air into the bowl portion 101. Indicates status. As shown in FIG. 4(c), the air blow damper 36a is closed when the air blow is stopped. As shown in FIG. 4D, when the blower 32 operates, the blower damper 36a is rotated and opened by the pressure (wind pressure) of the air sent from the blower 32. As shown in FIG. As a result, the blower 31 blows air from the upper rear portion of the bowl portion 101 toward the lower front portion of the bowl portion 101 as indicated by arrow C, for example. When executing the regular mist mode, air is blown in the direction of arrow C.

In the state of FIG. 4(e), the amount of air blown by the air blower 32 is greater (or the wind speed is higher) than in the state of FIG. 4(d). In this case, the blower damper 36a is further rotated and opened compared to the state of FIG. 4(d). As a result, the air blower 31 blows air from the upper rear portion of the bowl portion 101 toward the upper front portion of the bowl portion 101 as indicated by an arrow D, for example. When executing the aftermist mode, air is blown in the direction of arrow D. As shown in FIG. 4D, when the amount of air blown by the air blower 32 is small, the air is blown into the bowl 101 from the air blower port 120 at a large angle with respect to the horizontal plane. On the other hand, as shown in FIG. 4(e), when the air volume sent by the air blower 32 is large, the air is blown into the bowl portion 101 at a smaller angle (an angle closer to the horizontal plane) than when the air volume is small.

In this manner, the direction of the air blown from the air blowing section 32 is changed in the vertical direction by the air blowing damper 36 a that constitutes the air direction changing section 36 . That is, the control device 70 changes the air direction in the vertical direction by controlling the opening angle of the air blow damper 36a according to the air volume (air velocity) of the air blower 31 (air blower 32). In this case, even if the amount of air blown from the air blower 32 is the largest, the main stream of the airflow (the portion where the flow velocity is the highest) is made parallel or obliquely downward with respect to the horizontal plane by the air blow damper 36a.

Then, when executing the after mist mode, the control device 70 increases the air volume from the air blower 32 and blows the main stream of air at an angle close to the horizontal plane. As a result, the main flow of the airflow flowing into the bowl portion 101 from the air blowing port 120 can be directed along the rim portion 102 and the toilet seat back surface 14b. In this case, since the inner wall surface 104 of the rim portion 102 is arcuate, the airflow flows along the inner wall surface 104 into the gap S between the rim portion 102 and the toilet seat portion 14 .

On the other hand, when the regular mist mode is executed, the control device 70 reduces the air volume of the air blower 32 and directs the main stream of airflow from the air blower 120 to the inner wall of the toilet bowl 100 (more specifically, the opening projection part 101a). blow air toward In this case, the opening projection portion 101a is a surface facing upward (toward the opening 14c). As a result, the straight airflow sent out from the blower port 120 collides (reflects) with the opening projection portion 101a of the toilet bowl 100, thereby generating a large ascending airflow toward the opening 14c of the toilet seat portion 14. FIG.

The control device 70 controls the airflow direction changer 36 (airflow damper 36a) so that the direction of the airflow in the regular mist mode is lower than that in the aftermist mode. That is, the control device 70 controls the air blower 32 so that the air volume is smaller in the regular mist mode than in the after mist mode. In this case, the rising airflow generated inside the toilet bowl 100 is smaller in the after-mist mode than in the regular mist mode. Therefore, in the after-mist mode, the amount of mist M that lands on the toilet seat surface 14a can be made smaller than in the regular mist mode.

On the other hand, as shown in FIG. 5, a louver 36c that can be rotated by a motor 36b is provided behind the blower damper 36a. The motor 36b and the louver 36c change the direction of the wind in the horizontal direction in the bowl portion 101, and constitute a part of the wind direction changing portion 36. As shown in FIG. By driving the motor 36b, the control device 70 changes the direction of the louver 36c, thereby controlling the lateral direction of the air blown into the bowl portion 101 from the blower port 120. FIG. In FIG. 5, the louver 36c is tilted to the right in order to blow air to the right side of the toilet bowl 100. As shown in FIG. As a result, air flows along the inner surface of the toilet bowl 100 , so that a clockwise or counterclockwise swirling flow can be created inside the toilet bowl 100 .

When the after-mist mode and the regular mist mode are executed, the control device 70 changes the orientation of the louver 36c to turn the main stream of airflow into the interior of the toilet bowl 100 (bowl portion 101) when viewed from above. By placing the mist M sprayed from the spray device 60 on the airflow generated by the blowing from the air blower 31, the range where the mist M lands and the amount of the mist M landing in each range can be controlled.

FIG. 6 is a cross-sectional view of the main body and the spray device in FIG. 4(c) as viewed in the direction of arrows BB.
The body portion 12 is provided with a storage chamber 121 in which the spray portion 62 of the spray device 60 is stored. The storage chamber 121 includes a front wall portion 122 covering the front of the spraying portion 62, a bottom wall portion 123 covering the lower side of the spraying portion 62, and an outlet 124 provided between the front wall portion 122 and the bottom wall portion 123. and have The storage chamber 121 is a space surrounded in the front-back direction, the left-right direction, and the up-down direction except for the discharge port 124, and water W (tap water or sterilized water generated by the sterilization device 54) is filled inside. supplied.

The front wall portion 122 forms part of the front wall 12 a of the body portion 12 . The bottom wall portion 123 forms part of the bottom wall 12b of the main body portion 12 . The front wall portion 122 and the bottom wall portion 123 may be provided integrally with the body portion 12 or may be provided separately from the body portion 12 .

The discharge port 124 is provided between the front wall portion 122 and the bottom wall portion 123 . The discharge port 124 is located between the lower end 122a of the front wall portion 122 and the front end 123a of the bottom wall portion 123, and communicates the interior of the bowl portion 101 and the storage chamber 121 with each other. That is, the discharge port 124 is located below the toilet seat surface 14 a and discharges the mist M sprayed from the spray device 60 toward the inside of the toilet bowl 100 . Since the front wall portion 122 covers the entire front side of the spray device 60, even if urine or sewage splashed from the bowl portion 101 enters the storage chamber 121 through the discharge port 124, the spray device 60 will not be splashed. can be suppressed.

The discharge port 124 is open even when the mist M is not sprayed. In other words, the discharge port 124 always communicates between the inside of the toilet bowl 100 and the storage chamber 121 without being blocked by an openable/closable cover or the like. As a result, the air permeability of the storage chamber 121 is improved, so that residual water in the storage chamber 121 can be dried efficiently, and scale generation in the storage chamber 121 can be suppressed.

As shown in FIGS. 4 and 6, the discharge port 124 is positioned on the lower end side of the main body 12 and arranged on the other lateral side (right side) of the nozzle 58a (nozzle damper 58d). That is, the blower port 120 and the discharge port 124 are spaced apart in the left-right direction. In this case, a nozzle damper 58d (58a) is arranged between the blower port 120 and the discharge port . As a result, a predetermined space is provided between the blower port 120 and the discharge port 124 . Therefore, it is possible to suppress immediate interference between the air blown from the blower port 120 and the mist M discharged from the discharge port 124 .

As shown in FIG. 4, the outlet 124 has a horizontally elongated slit shape that is longer in the horizontal direction (horizontal direction) than in the vertical direction (vertical direction). As a result, it is possible to make it difficult for urine and sewage traveling from the upper side to the lower side (discharge port 124 side) of the front surface 122 b of the front wall portion 122 to enter the storage chamber 121 through the discharge port 124 .

On the other hand, as shown in FIG. 6, the bottom wall portion 123 has an upper surface 123b that slopes downward toward the discharge port 124 . As a result, the water W supplied into the storage chamber 121 can be discharged from the discharge port 124 into the bowl portion 101 along the upper surface 123 b of the bottom wall portion 123 . Therefore, it is possible to reduce the occurrence of residual water on the upper surface 123b of the bottom wall portion 123, so that it is possible to suppress the growth of scales and bacteria in the storage chamber 121.

The spray device 60 is provided inside the main body 12 . The spray device 60 is arranged below the toilet seat portion 14 in a state where the toilet seat device 10 is installed on the upper portion of the toilet bowl 100 , and sprays the mist M toward the inside of the toilet bowl 100 . Here, the state in which the spray device 60 is arranged below the toilet seat 14 means that at least part of the spray device 60 (the spray section 62 in this example) is below the toilet seat 14 . As a result, mist M of tap water or sterilized water is sprayed into the toilet bowl 100 from below the toilet seat 14 .

The spray device 60 has a motor 61 and a plate-shaped spray section 62 that is rotated by the motor 61 . Rotation of the motor 61 is controlled by the controller 70 . The spray part 62 is formed as a disc-shaped disk and arranged in the storage chamber 121 . In other words, the spray section 62 is surrounded.

A water supply port 43 a of the pipe line 43 is provided above the spray section 62 . Water W (tap water or sterilized water generated by the sterilizer 54) is supplied from the water supply port 43a to the upper surface 62a of the spray unit 62. As shown in FIG. When the motor 61 rotates, the driving force of rotation is transmitted to the spray section 62 and the spray section 62 rotates. Water W is supplied to the spraying section 62 while the spraying section 62 is rotating, so that the spraying section 62 sprays the water W in the form of mist. That is, the spray device 60 is of a rotary atomization type in which the mist M is generated by the rotation of the spray section 62 .

In addition, the water supply port 43a of the pipe line 43 is not limited to one, and a plurality of water supply ports 43a may be provided. FIG. 6 shows a case where one water supply port 43a is provided. For example, by arranging a plurality of water supply ports 43a at approximately equal intervals along the outer periphery of the spraying unit 62, the grain size and flow rate of the mist M around the spraying device 60 can be suppressed, and uniform spraying can be performed. can be done.

The spray device 60 sprays the mist M above the rectilinear airflow sent from the blower port 120 when executing the regular mist mode. As a result, the mist M is carried on the rising air current generated inside the toilet bowl 100, and the mist M can be efficiently landed on the toilet seat surface 14a.

The rotation direction of the motor 61 of the spray device 60 is controlled by the control device 70 . That is, when the after-mist mode and the regular mist mode are executed, the control device 70 rotates the spray unit 62 in the first rotation direction (for example, clockwise) and rotates the spray unit 62 in the first rotation direction. The motor 61 is controlled to switch between a state of rotating in a second rotating direction (for example, counterclockwise), which is the opposite direction. In this case, the controller 70 controls the direction of rotation of the motor 61 in accordance with the wind direction of the blower 31, so that the mist M can be efficiently carried on the rising air current.

As shown in FIG. 6, the spray part 62 has, for example, a conical shape, and has an inclined surface 62b that slopes downward from the upper end side toward the lower end side (outside in the radial direction) on which the water W is dropped (supplied). have. The inclined surface 62b of the spray section 62 is inclined toward the discharge port 124 on the front wall section 122 side. Then, the spray part 62 sprays the mist M from the radial outer end 62c of the inclined surface 62b.

As a result, the water W dropped onto the upper surface 62a of the rotating spraying section 62 spreads in a film on the spraying section 62 due to centrifugal force and is emitted from the end 62c. That is, the spray part 62 sprays the mist M radially when viewed from above (planar view). Moreover, the spray part 62 sprays the mist M obliquely downward with respect to the horizontal plane by having the inclined surface 62b. That is, the water W dripped onto the upper surface 62a of the spray section 62 is sprayed radially (horizontally long) from the end 62c toward the outlet 124. As shown in FIG.

Here, the water W splits from the end portion 62c of the spray portion 62 toward the discharge port 124 while remaining in the form of a film, or splits after becoming filamentous, and then becomes fine particles (mist M). The particle size and ejection speed of the mist M can be controlled by the rotation speed of the spraying part 62 , that is, the rotation speed of the motor 61 . In this case, the higher the rotation speed, the smaller the particle size of the mist M. The rotation speed of the motor 61 is set by experiments, simulations, etc. based on the shape, size, etc. of the spray section 62 . Further, the particle size of the mist M can be controlled by adjusting the flow rate of the water W supplied to the spray device 60 from the water supply port 43 a of the pipe line 43 .

The particle size is the particle size of fine particles existing in the air before landing on the bowl portion 101 and the toilet seat portion 14, for example, the Sauter mean particle size (total volume/total surface area). Further, the mist M refers to particles having a particle size in the range of 10 micrometers (μm) or more and 300 μm or less. If the particle size of the mist M is less than 10 μm, it takes a long time to wet the target portions such as the bowl portion 101, the rim portion 102, and the toilet seat portion 14 with the mist. In addition, when using sterilized water containing hypochlorous acid, if the particle size of the mist M is less than 10 μm, the concentration of hypochlorous acid in the mist M tends to decrease, and the sterilization performance tends to decrease. . On the other hand, if the particle size of the mist M is larger than 300 μm, the mist M is difficult to diffuse, making it difficult to spray the mist M over a wide area.

The toilet seat device 10 according to the present embodiment has the configuration as described above. Next, operations in the after-mist mode and the regular mist mode executed by the control device 70 will be described.
FIG. 7 is a flow chart showing control processing for the after-mist mode and regular mist mode performed by the control device. This control process is stored in advance in, for example, a memory (not shown) of the control device 70, and is repeatedly executed at a predetermined control cycle after the toilet seat device 10 is powered on. Note that each step in the flow chart shown in FIG. 7 uses the notation "S", for example, step 1 is indicated as "S1".

First, in S1, it is determined whether or not entry is detected. That is, based on the detection information of the human body detection sensor 22, the control device 70 determines whether or not the entry of the user into the toilet room has been detected. If "YES" in S1, that is, if it is determined that the user has entered the room, the process proceeds to S2. On the other hand, if "NO" is determined in S1, that is, if it is determined that no entry has been detected, the process proceeds to S4.

In S2, it is determined whether or not leaving the room is detected. That is, the control device 70 determines whether or not the user has left the toilet room based on the detection information of the human body detection sensor 22 . Then, if "YES" is determined in S2, that is, if it is determined that the user has left the room, the process proceeds to S3. On the other hand, if "NO" is determined in S2, that is, if it is determined that leaving the room has not been detected, the user's leaving the room is monitored.

At S3, the after mist mode is executed. That is, the control device 70 controls the blower device 31 and the spray device 60 to sterilize the inside of the toilet bowl 100 (the bowl portion 101) and the toilet seat back surface 14b with the mist M.

In the next S4, it is determined whether or not a predetermined time has passed. That is, the control device 70 determines whether or not a predetermined period of time has elapsed since the aftermist mode ended. The elapse of this predetermined time is for judging when the frequency of use of the toilet apparatus 1 has decreased. Therefore, the predetermined time is not set to several seconds or minutes, but is set to several hours (for example, 2 to 3 hours). This predetermined time is appropriately set depending on the installation location of the toilet device 1, etc., and is stored in the memory of the control device 70 in advance. Then, if it is determined "YES" in S4, that is, if it is determined that the predetermined time has passed, the process proceeds to S5. On the other hand, if "NO" is determined in S4, that is, if it is determined that the predetermined time has not elapsed, the process ends.

In S5, the periodic mist mode is executed. That is, the control device 70 controls the blower device 31 and the spray device 60 to sterilize the inside of the toilet bowl 100 (bowl portion 101), the toilet seat surface 14a, and the toilet seat back surface 14b by causing the mist M to land on the toilet seat back surface 14b. , is the end.

Next, the operation when executing the after mist mode will be described.
FIG. 8 is a schematic diagram showing the flow velocity state of the airflow in the after-mist mode.
FIG. 8(a) is a cross-sectional view of the toilet apparatus as seen from the side. FIG. 8(b) is a plan view of the toilet device as viewed from above.

The control device 70 causes the mist M to be sprayed by driving the spraying section 62 in a state in which the water W is supplied from the pipe line 43 (water supply section) to the upper surface 62a of the spraying section 62 . By spraying the mist M onto the inside of the toilet bowl 100 and the toilet seat portion 14 in this way, the cleanliness of the toilet seat device 10 can be maintained. However, since the after-mist mode is performed after the toilet device 1 is used, when the user sits on the toilet seat portion 14 immediately after spraying the mist M onto the toilet seat surface 14a, the user's buttocks get wet and the user feels uncomfortable. There is a risk of giving Therefore, in the present embodiment, the after-mist mode causes the mist M to land on the toilet seat back surface 14b while suppressing the mist M from landing on the toilet seat front surface 14a.

As shown in FIG. 8, when the toilet seat 14 is closed, the control device 70 controls the flow rate V1 between the toilet seat back surface 14b and the upper surface 103 of the rim portion 102 to exceed the flow velocity V1 flowing from the opening 14c toward the toilet seat surface 14a. The blower 31 is controlled so that the flow velocity V2 becomes higher (V1<V2). In this case, the flow velocity V1 can be measured on the same plane as the toilet seat surface 14a at a position X at a distance L1 (for example, L1=50 mm) toward the rear from the tip of the inner circumference of the opening 14c. Also, the flow velocity V2 can be measured at a position Y in front of the gap S between the upper surface 103 of the rim portion 102 and the toilet seat back surface 14b on the front end side of the toilet seat portion 14. FIG.

The air blown from the air blowing portion 32 of the air blowing device 31 is blown toward the inside of the toilet bowl 100 from the air blowing port 120 of the main body portion 12 . In this case, the blower port 120 is positioned at approximately the same height as the gap S between the rim portion 102 and the toilet seat portion 14 . Therefore, when executing the after-mist mode, the air volume of the air blower 32 is increased and the air blow damper 36a is largely opened. As a result, as shown by arrow D in FIG. The main stream of airflow flowing inside the toilet seat 100 can be made to flow along the toilet seat back surface 14b.

That is, in the aftermist mode, the main stream of wind (airflow) is sent out from the blower port 120 toward the rim portion 102 . The angle of the air blown from the blower port 120 obliquely downward with respect to the horizontal plane is such that, for example, when the flow velocity is measured at the front end position inside the toilet bowl 100, the flow velocity is maximized at the position of the inner wall surface 104 of the rim portion 102. angle can be set. The air blown out from the air blowing port 120 is guided to the gap S along the inner wall surface 104 of the rim portion 102 and flows outward. In this way, in the after-mist mode, by controlling the airflow of the air sent out from the blower 31, most of the air flowing from the inside of the toilet bowl 100 toward the outside is moved between the rim portion 102 and the toilet seat portion 14. Let it pass through the gap S.

Next, the control device 70 sprays the sterilized water mist M generated by the sterilization device 54 from the spray device 60 toward the inside of the toilet bowl 100 . In this case, the spray device 60 sprays the mist M along the toilet seat back surface 14b. Specifically, the spray device 60 sprays the mist M parallel or obliquely downward with respect to the horizontal plane. The obliquely downward angle of the mist M with respect to the horizontal plane is set so that the mist M can be efficiently placed on the air blown from the blower 31 . In this case, the spray angle of the mist M and the angle of the air blown from the blower 31 do not necessarily have to match, but the direction of the mist M sprayed from the sprayer 60 is determined by the direction of the air blown from the blower 31. By making the same direction as the direction as much as possible, the mist M can be easily carried on the wind.

In the after-mist mode, the motor 61 of the spray device 60 is rotated at high speed. As a result, the mist M having a small particle size is sprayed from the spray section 62 of the spray device 60 at a high flow rate. As a result, before the mist M falls inside the toilet bowl 100, it can be placed on the wind sent out from the blower 31. - 特許庁Then, the airflow containing the mist M is guided to the gap S between the toilet bowl 100 and the toilet seat portion 14, and the mist M can land on the upper surface 103 of the rim portion 102 and the toilet seat back surface 14b. In this case, since the airflow from the opening 14c of the toilet seat portion 14 toward the toilet seat surface 14a is weak, it is possible to prevent the toilet seat surface 14a from getting wet with the mist M. Further, even if the mist M lands on the toilet seat surface 14a, the amount of water that lands on the toilet seat surface 14a is small, so the toilet seat surface 14a can be dried early (before the next user uses it).

Next, the case of sterilizing the entire toilet seat back surface 14b by spreading the mist M over the entire toilet seat back surface 14b will be described.
FIG. 9 is a schematic diagram schematically showing a state in which mist is put on the airflow in the first turning direction.
FIG. 10 is a schematic diagram schematically showing a state in which mist is put on the airflow in the second turning direction.
FIG. 11 is a schematic diagram schematically showing a state in which mist is placed on an air current in a straight direction.
9 to 11, the mist M landing on the toilet seat back surface 14b is shown projected onto the upper surface 103 of the rim portion 102 for convenience of explanation.

The control device 70 controls the air blower 31 so that the main stream of the airflow blown from the air blower 31 swirls inside the toilet bowl 100 when viewed from above. Specifically, the control device 70 determines whether the main stream of the airflow blown from the blower device 31 is swirling inside the toilet bowl 100 in the first swirling direction when viewed from above, and whether the inside of the toilet bowl 100 is swirling in the first swirling direction. The wind direction changing unit 36 is controlled to switch between the state of turning in the second turning direction, which is the opposite direction. As shown in FIGS. 9 and 11, the first turning direction can be a clockwise turning direction inside the toilet bowl 100 . On the other hand, as shown in FIG. 10, the second turning direction can be a direction in which the inside of the toilet bowl 100 turns counterclockwise. Note that the first turning direction may be counterclockwise and the second turning direction may be clockwise.

As shown in FIG. 9, when the airflow is set to the first turning direction (clockwise), the motor 36b of the wind direction changing unit 36 is operated to tilt the louver 36c leftward. As a result, the air D1 is sent out from the air outlet 120 of the main body 12 toward the left side (left inner surface) of the toilet bowl 100 . As a result, the wind D1 flows from the left inner surface of the toilet bowl 100 to the front end side, so that an air current in the first turning direction can be generated inside the toilet bowl 100 . The airflow in the first turning direction escapes to the outside through the right side gap S of the gap S between the rim portion 102 and the toilet seat portion 14 .

In this case, the control device 70 operates the motor 61 so that the spray portion 62 of the spray device 60 rotates in the first rotation direction (clockwise). In this case, the mist M is radially sprayed from the outlet 124 of the storage chamber 121 in the same direction as the first swirling direction of the airflow. As a result, the mist M can be efficiently put on the airflow swirling in the first swirling direction. As a result, the mist M riding on the air current in the first turning direction can be delivered to the gap S between the right side portion 140b of the toilet seat back surface 14b and the rim portion 102. As shown in FIG. Therefore, the mist M can be efficiently landed on the right portion 140b of the toilet seat back surface 14b.

On the other hand, as shown in FIG. 10, when the airflow is set to the second turning direction (counterclockwise), the motor 36b of the wind direction changing unit 36 is operated to tilt the louver 36c to the right. As a result, the air D2 is sent out from the air outlet 120 of the main body 12 toward the right side (right inner surface) of the toilet bowl 100 . As a result, the wind D2 flows from the right inner surface of the toilet bowl 100 to the front end side, so that an air current in the second turning direction can be generated inside the toilet bowl 100 . The airflow in the second turning direction escapes to the outside through a gap S on the left side of the gap S between the rim portion 102 and the toilet seat portion 14 .

Then, the control device 70 operates the motor 61 so that the spray portion 62 of the spray device 60 rotates in the second rotation direction (counterclockwise). In this case, the mist M is radially sprayed from the outlet 124 of the storage chamber 121 in the same direction as the second swirling direction of the airflow. As a result, the mist M can be efficiently put on the airflow swirling in the second swirling direction. As a result, the mist M riding on the air current in the second turning direction can be delivered to the gap S between the left side portion 141b of the toilet seat back surface 14b and the rim portion 102. As shown in FIG. Therefore, the mist M can be efficiently landed on the left portion 141b of the toilet seat back surface 14b.

Further, as shown in FIG. 11, when the louver 36c of the airflow direction changing portion 36 is not tilted in either of the horizontal directions, the airflow D3 flows straight from the air outlet 120 toward the front end of the toilet bowl 100. As shown in FIG. In this case, since the blower port 120 is located on the left side in the horizontal direction, an airflow in the first turning direction (clockwise) is generated inside the toilet bowl 100 .

By rotating the spray part 62 of the spray device 60 in the first rotation direction, the mist M can be efficiently put on the air current inside the toilet bowl 100 . Since the wind D3 is sent toward the front end side of the toilet bowl 100, the mist M can be efficiently landed on the front end side portion 142b of the toilet seat back surface 14b by carrying the mist M on the wind D3.

Next, the operation when executing the regular mist mode will be described.
FIG. 12 is a schematic diagram showing the flow velocity state of the airflow in the regular mist mode.
FIG. 12(a) is a cross-sectional view of the toilet device as seen from the side. FIG. 12(b) is a plan view of the toilet device as seen from above.

In the periodic mist mode, the entire toilet seat device 10 is sterilized by spraying mist M made of sterilized water over the entire toilet bowl 100 and toilet seat portion 14 . Here, if the spraying device for spraying mist is provided below the toilet seat, it may be difficult for the mist to land on the surface of the toilet seat on which the user sits. Therefore, in the regular mist mode, even when the spraying device is arranged below the toilet seat, the mist M is effectively made to land on the toilet seat surface 14a by controlling the air blower 31 .

In the periodic mist mode, the control device 70 controls the spray device 60 and the blower device 31 to cause the mist M to land on the toilet seat surface 14a. In this regular mist mode, a mist M of sterile water is sprayed from the spray device 60 . The control device 70 puts the mist M on the wind sent from the air blower 31 and lands the mist M on the toilet seat surface 14a.

As shown in FIG. 12, in the regular mist mode, the airflow inside the toilet bowl 100 flows outward from the opening 14c of the toilet seat 14, and flows outward from between the rim 102 and the toilet seat 14. divided into air currents. In this case, the flow velocity V3 of the air flowing outward from the opening 14c of the toilet seat 14 is higher than the flow velocity V4 of the air flowing outward from between the rim 102 and the toilet seat 14 . That is, when the regular mist mode is executed, the control device 70 controls the flow velocity V4 between the toilet seat back surface 14b and the upper surface 103 of the rim portion 102 of the toilet bowl 100 when the toilet seat portion 14 is closed. The air blower 31 is controlled so that the flow velocity V3 flowing from the toilet seat surface 14a toward the toilet seat surface 14a becomes higher (V3>V4).

In this case, the flow velocity V3 can be measured on the same plane as the toilet seat surface 14a at a position X at a distance L2 (for example, L2=10 mm) from the tip of the inner circumference of the opening 14c toward the rear. Also, the flow velocity V4 is measured at a position Y at a distance L3 (for example, L3=20 mm) toward the front from the gap S between the upper surface 103 of the rim portion 102 and the toilet seat back surface 14b on the front end side of the toilet seat portion 14. be able to.

The air blown from the air blowing portion 32 of the air blowing device 31 is blown toward the inside of the toilet bowl 100 from the air blowing port 120 of the main body portion 12 . In this case, the blower port 120 is positioned at approximately the same height as the gap S between the rim portion 102 and the toilet seat portion 14 . Therefore, when the periodic mist mode is executed, the air volume of the air blower 32 is decreased and the air blow damper 36a is slightly opened. More specifically, the control device 70 controls the air blower 32 so that the air volume in the regular mist mode is smaller than the air volume in the after mist mode and the local drying mode.

As a result, as shown in FIG. 12(a), a straight airflow C1 is sent out obliquely downward from the blower port 120 at a large angle with respect to the horizontal plane. That is, in the periodic mist mode, the straight airflow C1 is sent from the blower port 120 toward the opening projection portion 101a of the inner wall of the toilet bowl 100 . The straight airflow C1 sent out from the blower port 120 forms an upward airflow C2 that rises toward the toilet seat surface 14a (opening 14c) after colliding with the opening projection portion 101a (inner wall of the toilet bowl 100). That is, the control device 70 controls the blower 31 so that the flow velocity (flow rate) of the ascending airflow C2 generated in the regular mist mode is higher than the flow velocity (flow rate) of the rising airflow generated in the after-mist mode.

Next, the control device 70 sprays the sterilized water mist M generated by the sterilization device 54 from the spray device 60 toward the inside of the toilet bowl 100 . In this case, the spray device 60 sprays the mist M parallel or obliquely downward with respect to the horizontal plane. At least part of the mist M sprayed from the spray device 60 interferes with the rising airflow C2 without interfering with the straight airflow C1. That is, when the regular mist mode is executed, the control device 70 directs the blowing direction of the straight airflow C1 blown from the blower 31 downward from the spraying direction of the mist M sprayed from the spraying device 60. Control. In other words, the mist M is emitted above the straight airflow C<b>1 sent from the blower port 120 .

In the regular mist mode, the motor 61 of the spray device 60 is rotated at high speed. As a result, the mist M having a small particle size is sprayed from the spray section 62 of the spray device 60 at a high flow rate. Further, the outlet 124 through which the mist M is sprayed and the blower outlet 120 through which the straight airflow is delivered are located on both left and right sides of the nozzle damper 58d. Also, the mist M is sprayed from the outlet 124 toward the rising air current C2.

As a result, the mist M is ejected forward of the toilet bowl 100 while suppressing interference with the straight airflow C1 as much as possible, and can be carried on the rising airflow C2 on the tip side of the toilet bowl 100. - 特許庁Then, the rising air current C2 containing the mist M is guided from the opening 14c of the toilet seat portion 14 to the toilet seat surface 14a, so that the mist M can land on the toilet seat surface 14a. That is, if the mist M is put on the straight airflow C1, a large amount of the mist M lands on the inner wall of the toilet bowl 100 . Therefore, in the regular mist mode, the mist M is caused to land on the toilet seat surface 14a efficiently by putting the mist M on the ascending air current C2.

Next, a case will be described in which the mist M is distributed over the entire toilet seat surface 14a to disinfect the entire toilet seat surface 14a.
FIG. 13 is a schematic diagram schematically showing the relationship between the airflow and the mist when the mist lands on the right side of the toilet seat surface in the regular mist mode.
FIG. 14 is a schematic diagram schematically showing the relationship between the airflow and the mist when the mist lands on the left side of the toilet seat surface in the regular mist mode.
FIG. 15 is a schematic diagram schematically showing a state in which mist is placed on the airflow in the first turning direction in the regular mist mode.
FIG. 16 is a schematic diagram schematically showing a state in which mist is placed on the airflow in the second turning direction in the regular mist mode.
FIG. 17 is a schematic diagram schematically showing a state in which mist is placed on straight-ahead airflow in the regular mist mode.

When the regular mist mode is executed, the control device 70 controls the blower device 31 so that the rising air current C2 circulates inside the toilet bowl 100 when viewed from above. The determination of the turning direction is controlled similarly in the regular mist mode and the after mist mode. That is, the control device 70 controls the state in which the updraft C2 swirls inside the toilet bowl 100 in the first swirling direction when viewed from above, and the state in which the inside of the toilet bowl 100 swirls in the second swirling direction opposite to the first swirling direction. The wind direction changing unit 36 is controlled to switch between the state of As shown in FIGS. 13, 15, and 17, the first turning direction can be a clockwise turning direction inside the toilet bowl 100. As shown in FIGS. On the other hand, as shown in FIGS. 14 and 16, the second turning direction can be a direction in which the inside of the toilet bowl 100 turns counterclockwise. Note that the first turning direction may be counterclockwise and the second turning direction may be clockwise.

As shown in FIGS. 13 and 15, in order to generate the updraft C21 in the first turning direction (clockwise), the motor 36b of the wind direction changing section 36 is operated to tilt the louver 36c leftward. As a result, a straight airflow C11 is sent out from the blower port 120 of the main body 12 toward the left side (left inner surface) of the toilet bowl 100 . This rectilinear airflow C11 is reflected by the inner wall (opening projection portion 101a) of the toilet bowl 100 to generate an upward airflow C21 that flows toward the right front end. The updraft C21 in the first turning direction passes through the opening 14c of the toilet seat portion 14 toward the right side portion 140a of the toilet seat surface 14a.

In this case, the control device 70 operates the motor 61 so that the spray portion 62 of the spray device 60 rotates in the first rotation direction (clockwise). As a result, the mist M is radially sprayed from the outlet 124 of the storage chamber 121 in the same direction as the first swirl direction of the upward airflow C21. As a result, the mist M can be efficiently put on the ascending airflow C21 swirling in the first swirling direction. As a result, the mist M riding on the updraft C21 in the first turning direction can be delivered to the right side portion 140a of the toilet seat surface 14a. Therefore, the mist M can be efficiently landed on the right portion 140a of the toilet seat surface 14a.

On the other hand, as shown in FIGS. 14 and 16, in order to generate the updraft C22 in the second turning direction (counterclockwise), the motor 36b of the wind direction changing unit 36 is operated to tilt the louver 36c rightward. . As a result, a straight airflow C12 is sent out from the air outlet 120 of the main body 12 toward the right side (right inner surface) of the toilet bowl 100 . This rectilinear airflow C12 is reflected by the inner wall (opening projection portion 101a) of the toilet bowl 100 to generate an upward airflow C22 flowing toward the left front end side. The updraft C22 in the second turning direction passes through the opening 14c of the toilet seat portion 14 toward the left side portion 141a of the toilet seat surface 14a.

In this case, the control device 70 operates the motor 61 so that the spray portion 62 of the spray device 60 rotates in the second rotation direction (counterclockwise). As a result, the mist M is radially sprayed from the outlet 124 of the storage chamber 121 in the same direction as the second swirl direction of the upward airflow C22. As a result, the mist M can be efficiently put on the updraft C22 swirling in the second swirling direction. As a result, the mist M riding on the updraft C22 in the second turning direction can be delivered to the left portion 141a of the toilet seat surface 14a. Therefore, the mist M can be efficiently landed on the left portion 141a of the toilet seat surface 14a.

Further, as shown in FIG. 17, when the louver 36c of the airflow direction changing portion 36 is not tilted in either of the right and left directions, a straight airflow C13 flows from the air outlet 120 toward the front end of the toilet bowl 100 in the straight direction. . In this case, since the air blowing port 120 is located on the left side in the left-right direction, an updraft C23 is generated in the first turning direction (clockwise).

In this case, by rotating the spray section 62 of the spray device 60 in the first rotation direction, the mist M can be efficiently put on the ascending airflow C23. Then, by putting the mist M on the rising air current C23, the mist M can be efficiently landed on the front end side portion 142a of the toilet seat surface 14a.

Thus, the toilet seat device 10 according to this embodiment has an after-mist mode in which the mist M is caused to land on the toilet bowl 100 and the toilet seat back surface 14b to suppress the mist M from landing on the toilet seat surface 14a, and In addition to 14b, a regular mist mode in which the mist M lands on the toilet seat surface 14a is also executed. Since the after-mist mode is executed every time the toilet apparatus 1 is used, it is possible to diligently disinfect the toilet bowl 100 and the toilet seat back surface 14b, which have a large dirt load. In addition, it is possible to prevent the user's buttocks from getting wet even when the user sits on the toilet seat immediately after the after-mist mode is executed.

On the other hand, in the regular mist mode, which is executed when the frequency of use of the toilet device 1 is low, the mist M lands on the toilet seat surface 14a as well, so the entire toilet seat device 10 can be sterilized. Therefore, by executing the after-mist mode and the regular mist mode in which the portions to be sterilized are made different from each other, the toilet seat device 10 can be provided with both cleanliness and usability.

Further, by controlling the blowing direction of the blower 31, an upward air current C2 can be generated inside the toilet bowl 100. FIG. Thereby, even if the spray device 60 is arranged below the toilet seat surface 14a, the mist M can be made to land on the toilet seat surface 14a. In addition, by controlling the air volume so as to change the magnitude of the ascending airflow C2, the single spray device 60 and the blower device 31 allow the mist M to land on the toilet seat back surface 14b so as not to overwet the toilet seat surface 14a. It is possible to switch between an after-mist mode in which mist M is applied and a regular mist mode in which mist M lands on the toilet seat surface 14a.

In addition, by setting the airflow direction downward in the regular mist mode, a large amount of airflow flows from the opening 14c of the toilet seat portion 14 toward the toilet seat surface 14a, so that a large amount of mist M lands on the toilet seat surface 14a. can be made In addition, by making the airflow in the after-mist mode more upward than in the regular mist mode, a large amount of airflow flows between the toilet seat back surface 14b and the upper surface 103 of the rim portion 102 of the toilet bowl 100, so that the toilet seat back surface 14b A large amount of mist M can land on the water. By executing the after-mist mode and the regular mist mode in this manner, the mist M can be effectively landed on the toilet seat front surface 14a and the toilet seat back surface 14b.

Further, in the regular mist mode, by reducing the air volume, the rectilinear airflow C1 is reflected on the inner wall of the toilet bowl 100 to generate an upward airflow C2. This makes it easier for a large amount of airflow to flow from the opening 14c of the toilet seat portion 14 toward the toilet seat surface 14a. As a result, in the regular mist mode, much mist M can land on the toilet seat surface 14a.

On the other hand, in the after-mist mode, the airflow that collides with the inner wall of the toilet bowl 100 rises along the inner wall of the toilet bowl 100 by setting the air volume to be larger than that in the regular mist mode. It becomes easy to flow between 103. As a result, in the after-mist mode, a large amount of mist M can land on the back surface 14b of the toilet seat. By executing the after-mist mode and the regular mist mode in this manner, the mist M can be effectively landed on the toilet seat front surface 14a and the toilet seat back surface 14b.

FIGS. 18(a) and 18(b) are schematic diagrams schematically showing modifications of the wind direction changing unit. In the above-described embodiment, the case where the louver 36c blows air in one direction to change the direction of the airflow has been described as an example. However, the present invention is not limited to this. For example, as in the modification shown in FIG. You may enable it to send. In this case, the air volume in a plurality of directions may be individually adjusted. Further, as in the modification shown in FIG. 18B, the wind direction changing unit 361 may change the direction of the airflow using the Coanda effect. In this case, when the air volume is large, the wind is sent out in the direction of arrow D13, and when the air volume is small, the wind is sent out in the direction of arrow D14. Further, the direction of the wind may be changed by forming a sub-flow channel in the air flow channel, or the direction of the wind may be changed by using a self-oscillating fluid element or the like.

Further, in the embodiment described above, the case where the spraying device 60 is of a rotary atomization type in which the mist M is generated by rotating the spraying unit 62 in which the water W is dropped has been described as an example. However, the present invention is not limited to this, and for example, an ultrasonic atomization device may be used as the atomization device. An ultrasonic atomizer irradiates a liquid with ultrasonic waves to mist the liquid. Also, for example, a two-fluid nozzle may be used as the spray device. A two-fluid nozzle jets both a gas and a liquid to mist the liquid. The direction of the mist sprayed from the spray device may be controlled, for example, by changing the orientation of the spray device itself.

Further, in the above-described embodiment, the case in which the opening angle of the blower damper 36a is changed according to the air volume to change the wind direction in the vertical direction has been described as an example. However, the present invention is not limited to this, and for example, the opening angle of the blower damper may be electrically changed to change the wind direction in the vertical direction. In this case, even if the air volume of the air blower 32 is constant, the vertical air direction can be changed.

The embodiments of the present invention have been described above. However, the invention is not limited to these descriptions. Appropriate design changes made by those skilled in the art with respect to the above-described embodiments 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, etc. of each element included in the toilet bowl, toilet seat device, etc. are not limited to those illustrated and can be changed as appropriate. Moreover, each element provided in each of the above-described embodiments can be combined as long as it is technically possible, and a combination thereof is also included in the scope of the present invention as long as it includes the features of the present invention.

Reference Signs List 1 toilet device 10 toilet seat device 12 body 12a front wall 12b bottom wall 14 toilet seat 14a toilet seat surface 14b toilet seat back 14c opening 16 toilet lid 20 seating detection sensor 22 human body detection sensor 24 Manual operation unit 26 Toilet seat motor 28 Toilet lid motor 30 Toilet seat heater 31 Air blower 32 Air blower 34 Warm air heater 36 Air direction changing unit 36a Air blow damper 36b Motor 36c Louver 40,41 , 42, 43 pipeline, 43a water supply port, 50 solenoid valve, 52 vacuum breaker, 54 sterilization device, 56 switching valve, 58 body washing function unit, 58a nozzle, 58b nozzle motor, 58c nozzle washing chamber, 58d nozzle damper, 60 Spray device 61 Motor 62 Spray section 62a Upper surface 62b Inclined surface 62c End 70 Control device 100 Toilet bowl 101 Bowl section 101a Opening projection section 102 Rim section 103 Upper surface 104 Inner wall surface 120 Blower mouth 121 storage chamber 122 front wall portion 122a lower end 122b front surface 123 bottom wall portion 123a front end 123b upper surface 124 outlet 140a, 140b right portion 141a, 141b left portion 142a, 142b front end portion , 360 wind direction changing part, 361 wind direction changing part, C1 straight air current, C2 rising air current, M mist, S gap, W water, V1, V2, V3, V4 flow velocity

Claims (5)

a toilet seat portion having a toilet seat surface on which a user sits, a toilet seat back surface located behind the toilet seat surface, and an opening penetrating between the toilet seat surface and the toilet seat back surface;
a spraying device for spraying mist;
a detection sensor that detects a user;
a control device that controls the spray device based on the detection information of the detection sensor;
with
The control device is
This is executed when the detection sensor changes from detecting the user to not detecting the user, and suppresses the mist from landing on the surface of the toilet seat and spreads the mist onto the back surface of the toilet seat. Aftermist mode to land on water,
A regular mist mode that is executed at a predetermined timing when the detection sensor does not detect the user and causes the mist to land on the surface of the toilet seat;
A toilet seat device comprising: a toilet seat portion having a toilet seat surface on which a user sits, a toilet seat back surface located behind the toilet seat surface, and an opening penetrating between the toilet seat surface and the toilet seat back surface;
a spraying device for spraying mist;
a detection sensor that detects a user;
a control device that controls the spray device based on the detection information of the detection sensor;
with
The control device is
an after-mist mode that is executed when the detection sensor changes from detecting the user to not detecting the user, and in which the mist lands on the front surface and the back surface of the toilet seat;
A regular mist mode that is executed at a predetermined timing when the detection sensor does not detect the user and causes the mist to land on the surface of the toilet seat;
has
The toilet seat device according to claim 1, wherein the amount of the mist that lands on the surface of the toilet seat in the after-mist mode is smaller than the amount of the mist that lands on the surface of the toilet seat in the periodic mist mode. A blower that generates an air current inside the toilet by blowing air toward the inside of the toilet,
The spray device is arranged below the toilet seat,
The air blower generates an upward air current that causes the mist sprayed from the spray device to rise from the inside of the toilet bowl toward the opening of the toilet seat,
3. The toilet seat apparatus according to claim 1, wherein the control device controls the air blower so that the rising air current is smaller in the after-mist mode than in the regular mist mode. The blower has an air direction changing unit that changes the blowing direction of the airflow,
4. The toilet seat apparatus according to claim 3, wherein the control device controls the airflow direction changer so that the direction of the airflow is lower in the regular mist mode than in the after-mist mode. The blower has a blower that changes the air volume,
5. The toilet seat apparatus according to claim 4, wherein the control device controls the air blower so that the air volume is smaller in the regular mist mode than in the after mist mode.

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