JP2017043995A - Toilet bowl - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a toilet bowl capable of efficiently washing inner surface of a bowl using a sterilizing solution.SOLUTION: A toilet bowl 1 comprises: a washing water supply unit 20 that supplies washing water along the inner face a bowl 10; a sterilizing solution supply unit 26 that supplies a sterilizing solution of a flow rate smaller than that of the washing water along the inner face of the bowl; and a control unit 18 that, when a wash operation is made, controls the washing water supply unit to supply the washing water, and subsequently to control the sterilizing solution supply unit to supply the sterilizing solution.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a toilet device.

Conventionally, a toilet device for supplying a sterilizing liquid to a bowl portion is known. Although it is conceivable to use such a sterilizing liquid as cleaning (large cleaning) water after use, in that case, a large amount of sterilizing liquid is required.
For example, in the following Patent Document 1, an ozone water tank for storing ozone water is provided in a washing tank, and after flushing the washing water in the washing tank to the toilet bowl side, the toilet bowl washing device for flowing the ozone water to the toilet bowl side Is disclosed.

JP 11-71797 A

  However, in the toilet bowl cleaning device described in Patent Document 1, the ozone water flowing out to the toilet bowl with the float valve of the ozone water tank being opened flows out comparatively vigorously like the flush water. Therefore, it is considered that most of the ozone water is discharged without contacting the inner surface of the bowl portion, and further improvement is desired.

  This invention is made | formed in view of the said situation, and it aims at providing the toilet device which can wash | clean the inner surface of a bowl part effectively with a disinfection liquid.

  In order to achieve the above object, a toilet device according to the present invention includes a cleaning water supply unit that supplies cleaning water along the inner surface of the bowl portion, and a sterilizing liquid having a smaller flow rate than the cleaning water. If the cleaning operation is performed, the cleaning water supply unit is controlled to supply the cleaning water, and then the sterilizing liquid supply unit is controlled to control the sterilizing liquid. And a control unit for supplying the power.

  The toilet device according to the present invention is configured as described above, so that the inner surface of the bowl portion can be effectively washed with the sterilizing liquid.

1 is a partially omitted schematic longitudinal sectional view schematically showing an example of a toilet device according to an embodiment of the present invention. FIG. 2 is a partially omitted schematic longitudinal sectional view corresponding to FIG. 1. It is a schematic time chart which shows typically an example of the basic operation performed in the toilet device. It is a schematic time chart which shows typically other examples of basic operation performed in the toilet device. It is a schematic time chart which shows typically the other example of the basic operation performed in the toilet device. (A), (b) is the partially broken schematic longitudinal cross-sectional view which abbreviate | omitted one part which shows typically an example of the toilet device which concerns on other embodiment of this invention.

Embodiments of the present invention will be described below with reference to the drawings.
In the following embodiments, directions such as up and down directions will be described with reference to a state in which the toilet device is installed.
3 to 5, the horizontal axis is the time axis, the vertical axis is the water level of the bowl portion, and the transition is schematically shown. In these schematic time charts, the vertical movement of each device is shown. And schematically shows an opening / closing operation and the like.

FIG.1 and FIG.2 is a figure which shows typically an example of the toilet device which concerns on 1st Embodiment.
As shown in FIGS. 1 and 2, the toilet device 1 according to the present embodiment is a seated so-called Western-style toilet device installed on an installation surface such as a floor.
The toilet device 1 has a cleaning water supply unit 20 that supplies cleaning water so as to be along the inner surface of the bowl part (toilet bowl) 10 and a sterilizing liquid having a smaller flow rate than the cleaning water so as to be along the inner surface of the bowl part 10. And a sterilizing liquid supply unit 26 for supplying to the liquid. The toilet device 1 also includes a drainage mechanism connected to the external drainage pipe 3. In addition, the toilet device 1 is provided with a toilet seat 4 and a toilet lid 5 that are openable and closable with respect to the bowl portion 10.

In addition, the toilet device 1 has various functional devices and functions such as an opening / closing device that opens and closes the toilet seat 4 and the toilet lid 5, a deodorizing device, a local cleaning device, a heating device that warms the toilet seat 4 and water for local cleaning, and a detergent supply device. It is good also as a structure which provided the member.
The toilet device 1 may be provided with various sensors such as a human body detection sensor, a seating sensor, a toilet seat sensor that detects opening and closing of the toilet seat 4 and the toilet lid 5, and a toilet lid sensor. Further, the toilet device 1 may be provided with a remote control device as an operation unit for operating the various functional devices described above, a transmission / reception device that enables transmission / reception of various signals of the remote control device, and the like.

The bowl portion 10 has a mortar shape that opens upward, and has a rim portion 11 at the upper end. Moreover, the drain pipe part 12 is provided in the lower part (bottom part) of the bowl part 10 so that it may extend toward the back side. The drain pipe portion 12 is provided with a trap portion 13 that communicates with the external drain pipe 3 and constitutes a drain mechanism.
Moreover, in this embodiment, as shown in FIG.1 and FIG.2, it is set as the structure provided with the water level variable mechanism 13 which can maintain the water level of the bowl part 10 in the low water level LV2 lower than the stored water level LV1. In the present embodiment, the trap portion 13 constitutes a water level variable mechanism in which the connection port 14 at one end is connected to the drain pipe portion 12 and the drain port 15 side at the other end is moved up and down. That is, the trap portion 13 is a so-called turn trap type.

The trap portion 13 has a drainage position in which the drainage port 15 faces upward and allows the water to be stored in the bowl unit 10, the drainage port 15 is in a low water level lower than the pooled water location, and the drainage port 15 is directed to the lower side. It is set as the structure switched to a position.
Moreover, the trap part 13 is made into the bellows cylinder shape so that the edge part by the side of the drain port 15 can be displaced to an up-down direction. Moreover, the trap part 13 is accommodated in the trap case provided in the toilet device 1 so that the drain pipe part 12 of the bowl part 10 and the external drain pipe 3 are connected.
The toilet device 1 is provided with a drive mechanism that moves the end of the trap portion 13 on the drain port 15 side up and down. As such a drive mechanism, one end portion is rotatably held around the arm shaft 17 by a rotary drive portion such as a motor, and the connecting portion at the other end portion is connected to the end portion on the drain port 15 side of the trap portion 13. The drive arm 16 may be provided.

The switching of the trap unit 13 to each position, that is, the rotational drive of the drive arm 16 is performed by an operation of a cleaning operation unit 21 (see FIG. 3), which will be described later, so that drainage and accumulated water can be performed. The flush water supply operation of the toilet device 1 is interlocked.
As shown by the solid line in FIG. 1, in a state where the drainage port 15 of the trap unit 13 can be stored with the drainage port 15 facing upward (pumped water position), water is accumulated until the drainage port 15 of the trap unit 13 is substantially reached. The drain pipe portion 12 of the bowl portion 10 is sealed. This stored water level LV1 may be a general water level. Further, the stored water level LV1 may be set to an appropriate level so that the surface of the stored water in the bowl portion 10 does not become too low, for example, from the viewpoint of preventing drying of the inner surface of the bowl portion 10 and adhesion of dirt to the inner surface. Therefore, the water level may be set appropriately so that a relatively large water surface is formed.

On the other hand, as shown by a two-dot chain line in FIG. 1, drainage is performed at the drainage position where the drainage port 15 of the trap part 13 can be drained downward, and the water level of the bowl part 10 is lowered.
In addition, as shown in FIG. 2, if the trap arm 13 is driven to rotate so that the drain port 15 of the trap portion 13 is below the above-described water storage position to bring the trap portion 13 to a low water level position, The water level of the part 10 becomes a low water level LV2 lower than the accumulated water level LV1. At the low water level LV2, the inner surface of the bowl portion 10 below the stored water level LV1 as a normal water line is exposed. The low water level LV2 may be a water level that is at least higher than the breaking level, may be a water level that is 10 mm or more lower than the stored water level LV1, and may be a water level that is 20 mm or more and lower. In addition, this low water level LV2 is determined depending on the viewpoint of effectively attaching the sterilizing liquid supplied from the sterilizing liquid supply unit 26 described later to the inner surface of the bowl unit 10, evaporation, temporary negative pressure on the drainage destination side, or the like. It is good also as an appropriate water level so that breakage does not occur easily.

The washing water supply unit 20 includes water supply lines 22 and 24 connected to a water supply pipe (water pipe) 2 that serves as a water supply source. In the present embodiment, the flush water supply unit 20 is a direct water pressure type, and the toilet apparatus 1 is a so-called tankless type that does not include a flush tank.
The water supply lines 22 and 24 are provided with a cleaning water supply valve 23 for supplying or blocking water supply to the bowl unit 10. In the present embodiment, a branch water supply line 27 for supplying water toward a sterilizing liquid generator 28 described later is provided so as to branch from the water supply lines 22 and 24. Further, the washing water supply valve 23 is a three-way switching valve to which the branch water supply line 27, the water supply source side line 22 and the water supply destination side line 24 of the water supply lines 22, 24 are connected. That is, if the washing water supply valve 23 is switched to the water supply side so that the water supply source side line 22 and the water supply destination side line 24 are connected, and the water supply destination side is switched, the water is supplied from the water supply source to the bowl unit 10. The On the other hand, if the washing water supply valve 23 is switched to the sterilizing liquid generation unit 28 side so that the water supply source side line 22 and the branch water supply line 27 communicate with each other and is switched to the sterilizing liquid generation unit side switching state, the sterilizing liquid is supplied from the water supply source. Water is supplied to the generator 28. Moreover, if the washing water supply valve 23 is switched to the closed state in which the water supply is shut off, the water supply is stopped.

Further, a water supply port 25 that supplies cleaning water toward the rim portion 11 is provided at the end of the water supply destination side line 24.
The water supply port 25 is provided so as to supply cleaning water along the rim portion 11 of the bowl portion 10. In the present embodiment, the rim portion 11 is a so-called open rim provided with a concave groove so as to open toward the center of the bowl portion 10 in plan view and to extend in the circumferential direction. The cleaning water supplied from the water supply port 25 along the concave groove reaches the drain pipe 12 while turning along the inner surface of the bowl 10.
The supply of the cleaning water by the cleaning water supply unit 20 is performed by the cleaning operation of the cleaning operation unit 21 provided in the toilet device 1. Such a washing operation unit 21 may be an operation lever, an operation button, or the like, and various sensors such as a human body detection sensor and a seating sensor are grasped as a washing operation unit, that is, a mode in which detection is grasped as an operation. It is good.

In this embodiment, the sterilizing liquid supply unit 26 includes a sterilizing liquid generating unit 28 that generates a sterilizing liquid.
The sterilizing liquid generation unit 28 is connected to the branch water supply line 27 and a supply line 29 that supplies the sterilizing liquid generated in the sterilizing liquid generation unit 28 toward the bowl unit 10. In addition, it replaces with the aspect which made the above-mentioned washing water supply valve 23 into the three-way switching valve, and makes it the on-off valve which opens and closes the water supply lines 22 and 24, and supplies the water supply to the sterilization liquid production | generation part 28 to the branch water supply line 27 or It is good also as a structure etc. which provided the on-off valve which interrupts | blocks. In addition, instead of the mode in which the water supply to the sterilizing liquid generation unit 28 is performed via the water supply line 22 common to the cleaning water supply unit 20, the water supply may be performed separately via the water supply line.

  Moreover, in this embodiment, it is set as the structure connected so that the supply line 29 may merge with the water supply destination side line 24 of the washing water supply part 20. FIG. In other words, the sterilizing liquid generated in the sterilizing liquid generating unit 28 is supplied from the water supply port 25 toward the rim part 11 of the bowl part 10 through the supply line 29 and the water supply side line 24 in the same manner as the cleaning water. The supply line 29 is provided with a sterilizing liquid supply valve 29a for supplying or blocking the sterilizing liquid. The sterilizing liquid supply valve 29a may be an open / close valve (ON / OFF valve). In addition, it is good also as a structure which provided the backflow prevention mechanisms, such as a non-return valve, without providing such a sterilization liquid supply valve 29a. Further, instead of the aspect in which the supply line 29 is connected to join the water supply destination side line 24 of the cleaning water supply unit 20, the sterilizing liquid is supplied to the bowl portion separately from the supply of the cleaning water from the cleaning water supply unit 20. 10 may be provided. In other words, a supply port for supplying the sterilizing liquid toward the bowl portion 10 may be provided at the end of the supply line 29 separately from the water supply port 25.

Moreover, the sterilization liquid production | generation part 28 is set as the structure which produces | generates the ozone water as a sterilization liquid in this embodiment. Moreover, the sterilizing liquid production | generation part 28 is set as the structure which electrolyzes water and produces | generates ozone water. That is, the sterilizing liquid generating unit 28 is an electrolytic type.
The sterilizing liquid generator 28 is configured to have a pair of electrodes 28 a and 28 a that are connected to a power source and constitute an anode and a cathode in an electrolytic cell connected to the branch water supply line 27. Moreover, the sterilizing liquid production | generation part 28 is set as the structure which provided the polymer electrolyte membrane 28b between a pair of electrodes 28a and 28a. Moreover, in the electrolytic cell of the sterilizing liquid production | generation part 28, the melt | dissolution part which melt | dissolves the ozone gas produced | generated by electrolysis in water is provided. Such an electrolytic sterilization liquid generator 28 may have various other configurations.

If this sterilization liquid production | generation part 28 is started and the washing water supply valve 23 is switched to the sterilization liquid production | generation part 28 side, it will supply with electricity to a pair of electrodes 28a and 28a, ozone gas will be produced | generated, and it will be melt | dissolved in water in a melt | dissolution part. Water is produced. The ozone water generated in the sterilizing liquid generation unit 28 is supplied to the bowl unit 10 via the supply line 29 and the water supply destination side line 24. In addition, if the sterilizing liquid production | generation part 28 is started, you may make it open the sterilizing liquid supply valve 29a immediately or if predetermined | prescribed delay time passes.
Further, depending on the configuration of the sterilizing liquid generation unit 28, a gas-liquid mixing unit that dissolves ozone gas in water may be provided. As such a gas-liquid mixing part, it is good also as what was set as appropriate structures, such as a crushing type, a shearing type, a pressurization dissolution type, and an ejector type, for example. Moreover, it is good also as what was set as the structure which can change the ozone concentration of the disinfection liquid production | generation part 28. FIG. Further, in the illustrated example, the sterilizing liquid generation unit 28 is provided in the upper case portion 6 provided in the upper part on the back side of the bowl portion 10, but is provided at an appropriate location of the toilet device 1. You may do it.

  The sterilizing liquid is not limited to ozone water, and may be, for example, hypochlorous acid water, strong acid water, sodium hypochlorite solution, hydrogen peroxide water, or the like. The sterilizing solution may be any one having higher sterilizing properties than tap water, and is not limited to the above-described electrolyzed water or sterilizing solution having low persistence, but also various other types such as alcohol-based sterilizing solutions such as ethanol. It is good also as sterilizing liquid. Depending on the type of the sterilizing liquid, an appropriate sterilizing liquid generating unit 28 is provided in the sterilizing liquid supplying unit 26, or the sterilizing liquid supplying unit 26 does not generate the sterilizing liquid and stores a sterilizing liquid. The part may be provided in the sterilizing liquid supply unit 26. In this case, it is good also as a structure which provided the appropriate opening-and-closing lid | cover etc. for supplying a sterilizing liquid to a storage part. Further, for example, a flow rate adjusting valve is provided in the water supply lines 22 and 24 of the cleaning water supply unit 20 and a pipe for mixing a sterilizing component in the cleaning water is connected. It is good also as an aspect etc. which can squeeze and can supply a small flow-rate sterilization liquid.

  Further, the flow rate of the sterilizing liquid supplied from the sterilizing liquid supply unit 26 is set smaller than the flow rate of the cleaning water supplied from the above-described cleaning water supply unit 20. The flow rate of the sterilizing liquid may be an appropriate flow rate so that the sterilizing liquid effectively contacts the inner surface of the bowl portion 10. If the flow rate of the sterilizing liquid is too small, it tends to be difficult to make contact over a wide area of the inner surface of the bowl portion 10, while if it is too large, the film thickness when flowing along the inner surface of the bowl portion 10 is increased. Therefore, there is a tendency that the amount flowing without contacting the inner surface of the bowl portion 10 increases. From this point of view, that is, the flow rate of the sterilizing liquid is appropriately set according to the shape of the inner surface of the bowl portion 10 so as to be in contact with the inner surface of the bowl portion 10 over a wide range and to reduce the film thickness. It may be. Moreover, it is good also as an aspect which provided the flow regulating valve etc. suitably in the supply line 29 or the branch water supply line 27 so that the flow volume of a disinfection liquid may become an appropriate flow volume.

In addition, the toilet device 1 includes a control unit 18 that controls the cleaning water supply unit 20 to supply the cleaning water and then controls the sterilizing liquid supply unit 26 to supply the sterilizing liquid when the cleaning operation is performed. ing.
The control unit 18 is connected to the drive mechanism of the trap unit 13, the cleaning operation unit 21, the cleaning water supply valve 23, the sterilizing liquid generation unit 28, the sterilizing liquid supply valve 29a, and the like through signal lines and the like. To control the operation. In the example shown in the figure, the control unit 18 is provided in the upper case unit 6, but may be provided in another part, or a remote controller provided in the toilet device 1 installed on a wall surface or the like. You may make it provide in an apparatus.
The control unit 18 includes a control unit such as a CPU, a memory, and the like, and a storage unit that stores various operation programs and the like.

Each part is controlled by this control part 18, and each basic operation example described later is executed.
Hereinafter, an example of the basic operation executed in the toilet device 1 according to the present embodiment will be described with reference to FIG.
In this operation example, the control unit 18 is configured to supply the sterilizing liquid in a state where the water level of the bowl unit 10 is lower than the accumulated water level LV1. Moreover, the control part 18 is set as the structure which supplies a disinfection liquid in the state whose water level of the bowl part 10 is the low water level LV2.
Further, in this operation example, the control unit 18 is configured to control the sterilizing liquid supply unit 26 and the trap unit 13 so that the supply of the sterilizing liquid is continued from the low water level LV2 to reach the stored water level LV1. .

  First, as shown in FIG. 3, when the cleaning operation (ON operation) of the cleaning operation unit 21 is performed, the cleaning water supply valve 23 is changed from the shut-off state (closed state) to the water supply destination side switching state (open state). Accordingly, the cleaning water is supplied from the water supply port 25 toward the bowl portion 10. At this time, in the example shown in the figure, the trap portion 13 is displaced to the drainage position after being set to the upper position higher than the accumulated water position. Thereby, the water level of the bowl part 10 can be raised temporarily rather than the stored water level LV1, and the transportability of filth etc. at the time of setting it as a drainage position can be improved. In the example shown in the figure, the trap unit 13 is switched to the upper position after the cleaning water supply valve 23 is switched to the water supply side switching state. However, after the trap unit 13 is switched to the upper position, the cleaning is performed. The water supply valve 23 may be switched to the water supply destination side switching state.

Moreover, if the trap part 13 is made into a drainage position, it will drain and the water level of the bowl part 10 will fall gradually, and if the predetermined time passes, the trap part 13 will be switched to a stored water position. Thereby, the water level of the bowl part 10 rises and becomes the stored water level LV1. Thus, if it becomes the stored water level LV1, the cleaning water supply valve 23 will be closed, the supply of cleaning water will be stopped, and the trap part 13 will be displaced from a stored water position to a low water level position. Thereby, the water level of the bowl part 10 falls and it becomes the low water level LV2.
In this operation example, the sterilizing liquid is supplied in a state where the water level of the bowl portion 10 is at the low water level LV2. In the illustrated example, when the trap unit 10 is in the low water level position, the cleaning water supply valve 23 is switched from the closed state to the sterilizing liquid generation unit side, and the sterilizing liquid supply valve 29a is opened. Further, in the illustrated example, the switching from the closed state of the cleaning water supply valve 23 to the sterilizing liquid generation unit side and the opening of the sterilizing liquid supply valve 29a are performed immediately after the trap unit 13 is at the low water level position. Although an example is shown, it may be performed before and after the low water level position. 3-5, although the sterilizing liquid production | generation part 28 is abbreviate | omitted, ON / OFF is made in conjunction with the switching to the sterilization liquid production | generation part side switching state of the washing water supply valve 23. FIG.

  In this state, the sterilizing liquid is supplied along the inner surface of the bowl portion 10, and the sterilizing liquid directly comes into contact with a portion below the stored water level LV <b> 1. Further, with the supply of the sterilizing solution, the trap portion 13 is drained in an overflow state. And the trap part 13 is displaced to a stored water position, continuing supply of a disinfection liquid. Thereby, the water level of the bowl part 10 rises and becomes the stored water level LV1. Further, when the water level of the bowl portion 10 reaches the accumulated water level LV1, the cleaning water supply valve 23 and the sterilizing liquid supply valve 29a are closed. In the example shown in the figure, the cleaning water supply valve 23 and the sterilizing liquid supply valve 29a are closed immediately after the trap unit 13 reaches the water storage position. For example, the supply of the sterilizing liquid may be continued even after the trap unit 13 reaches the water storage position. The switching of the trap unit 13 from the low water level position to the accumulated water position may be performed when a predetermined time has elapsed. Further, the supply control of the cleaning water and the sterilizing liquid may be time control or flow rate control, and appropriate control may be performed so that the water level of the bowl portion 10 becomes the accumulated water level LV1.

The toilet device 1 according to the present embodiment is configured as described above, so that the inner surface of the bowl portion 10 can be effectively washed with a sterilizing liquid.
That is, if a cleaning operation is performed, the controller 18 is configured to control the cleaning water supply unit 20 to supply cleaning water, and then control the sterilizing liquid supply unit 26 to supply the sterilizing liquid. Further, the sterilizing liquid supply unit 26 is configured to supply a sterilizing liquid having a flow rate smaller than that of the cleaning water so as to be along the inner surface of the bowl part 10. Therefore, the amount of the sterilizing liquid can be reduced as compared with the case where the entire amount of the washing water is the sterilizing liquid. Further, the sterilizing liquid can be effectively brought into contact with the inner surface of the bowl portion 10 as compared with the case where a sterilizing liquid having the same flow rate as that of the cleaning water is supplied. Can be used. Thereby, the amount of sterilizing liquid required can be reduced more effectively, and the device (sterilizing liquid generating unit 28) that generates the sterilizing liquid can be downsized, or the load on the sterilizing liquid generating unit 28 can be reduced. be able to.

  Further, in the above-described operation example, the sterilizing liquid is supplied in a state where the water level of the bowl unit 10 is lower than the accumulated water level LV <b> 1 by the control of the control unit 18. Accordingly, the sterilizing liquid can also be brought into direct contact with the inner surface of the bowl portion 10 below the stored water level LV1, for example, compared to the case where the sterilizing liquid is supplied to the bowl portion 10 in the stored water state. The inner surface of the bowl portion 10 can be cleaned more effectively.

  Further, in the above-described operation example, the control unit 18 controls the sterilization liquid supply unit 26 and the water level variable mechanism (trap unit) 13 so that the supply of the sterilization liquid is continued from the low water level LV2 to reach the stored water level LV1. It is set to be made. Accordingly, for example, the inner surface of the bowl portion 10 can be kept more effective and clean as compared with the case where the low water level LV2 is left as it is, or the low water level LV2 is set and then the stored water level LV1 is set by washing water. Can do.

Next, another example of the basic operation executed in the toilet device 1 according to the present embodiment will be described with reference to FIG. Note that description of operations similar to the above-described operation examples will be omitted or briefly described.
In the above-described operation example, with the cleaning operation, the cleaning water is supplied and the water level is set to LV1 with the cleaning water, and then the trap unit 13 is displaced to the low water level position to supply the sterilizing liquid as the low water level LV2. An example is shown. On the other hand, in this operation example, the supply of the cleaning water is continued from the drained state until the low water level LV2 is reached, and then the supply is switched to the supply of the sterilizing liquid so that the stored water level LV1 is obtained.
That is, as shown in FIG. 4, if the cleaning operation (ON operation) of the cleaning operation unit 21 is performed as described above, the cleaning water supply valve 23 is switched from the shut-off state (closed state) to the water supply side switching state (open state). Then, the trap portion 13 is displaced from the accumulated water position to the upper position and then displaced to the drainage position.

Moreover, the trap part 13 is made into a drainage position, and if the predetermined time passes, the trap part 13 will be switched to a low water level position. Thereby, the water level of the bowl part 10 rises and becomes the low water level LV2. In this operation example, when the low water level LV2 is reached, the supply of the cleaning water is switched to the supply of the sterilizing liquid. That is, the cleaning water supply valve 23 is switched from the water supply destination side switching state to the sterilizing liquid generation unit side, and the sterilizing liquid supply valve 29a is opened. In the illustrated example, the switching from the water supply destination side switching state of the cleaning water supply valve 23 to the sterilizing liquid generation unit side and the opening of the sterilizing liquid supply valve 29a are performed immediately after the trap unit 13 is at the low water level position. Although an example is shown, it may be made before and after the low water level position.
Then, similarly to the above, when the trap unit 13 is displaced to the accumulated water position while the supply of the sterilizing liquid is continued, and the water level of the bowl unit 10 reaches the accumulated water level LV1, the washing water supply valve 23 and the sterilizing liquid supply valve 29a. Is closed.
This operation example also provides substantially the same effect as the above operation example. In addition, compared with the above-described operation example, it is possible to save water for cleaning water.

Next, still another example of the basic operation executed in the toilet device 1 according to the present embodiment will be described with reference to FIG. Note that description of operations similar to those of the above-described operation examples will be omitted or briefly described.
In each of the above operation examples, an example is shown in which the stored water from the low water level LV2 to the stored water level LV1 is made with the sterilizing liquid, but in this operation example, the mode is made with the wash water.

That is, as shown in FIG. 5, as described above, cleaning water is supplied along with the cleaning operation, and the trap portion 13 is displaced to the upper position, the drainage position, and the stored water position. Then, as described above, the sterilizing liquid is supplied in a state where the trap unit 13 is at the low water level position. In this operation example, the trap unit 13 is switched from the supply of the sterilizing liquid to the supply of the cleaning water when switching from the low water level position to the stored water position. In the illustrated example, immediately after the trap unit 13 starts to be displaced from the low water level position toward the accumulated water position, the sterilizing liquid supply valve 23 is switched from the sterilizing liquid generating unit side switching state to the water supply destination side and the sterilizing liquid. Although an example in which the supply valve 29a is closed is shown, it may be made before and after that. As a result, the water level of the bowl portion 10 rises due to the supply of the cleaning water, reaches the stored water level LV1, and when the stored water level LV1 is reached, the cleaning water supply valve 23 is closed in the same manner as described above.
This operation example also provides substantially the same effect as the above operation example.

Next, another embodiment according to the present invention will be described with reference to the drawings.
Drawing 6 is a figure showing typically an example of the toilet device concerning a 2nd embodiment.
Note that differences from the first embodiment will be mainly described, and the same components will be denoted by the same reference numerals, and description thereof will be omitted or briefly described.

As shown in FIG. 6, the toilet device 1 </ b> A according to the present embodiment is mainly different from the first embodiment in the aspects of the rim portion 11 </ b> A and the drainage mechanism.
In the present embodiment, the rim portion 11A is not an open rim as described above, but a hollow cylindrical shape. The rim portion 11A is provided with a large number of rim holes so as to open downward, and the base end portion thereof communicates with the cleaning water supply unit 20 and the sterilizing liquid supply unit 26 similar to the above. A water supply port 25A is provided. The cleaning water or the sterilizing liquid supplied through the water supply port 25A flows down from the rim hole while passing through the hollow portion of the rim portion 11A, and is supplied along the inner surface of the bowl portion 10A.

In the present embodiment, the drainage mechanism is a so-called siphon in which a jet hole is provided so as to open on the bottom side of the bowl portion 10A, and a trap portion 13A is provided on the bottom side of the bowl portion 10A so as to face the jet hole. It is a zette type. That is, in the present embodiment, the trap portion 13A is a fixed trap that constitutes a drainage flow path. It should be noted that the present invention is not limited to the siphon jet type as shown in the figure, and may be provided with other drainage mechanisms such as a siphon type, a siphon vortex type, a neo vortex type, and a wash-off.
The trap portion 13A communicates with the bottom portion of the bowl portion 10A, extends obliquely upward from an end serving as a trap inlet constituting the drain pipe portion 12A, and is provided to bend obliquely downward from the trap top portion. And connected to the external drainage pipe 3 (see FIG. 1).

In the present embodiment, the trap portion 13A is provided with a water level variable mechanism 19 that can maintain the water level of the bowl portion 10A at a low water level LV2 lower than the accumulated water level LV1. In the first embodiment, an example in which the trap portion 13A itself is made variable is shown. However, in this embodiment, a part of the wall portion constituting the flow path of the trap portion 13A is replaced with a movable wall constituting the water level variable mechanism. This is part 19.
The movable wall portion 19 is configured to be displaced so as to move the trap top portion up and down. In the example shown in the figure, the movable wall portion 19 is supported so that the base end portion is rotatable about an axis along the toilet width direction. Further, a drive unit such as a motor for rotating the movable wall portion 19 around the axis is provided at an appropriate position of the toilet device 1A. Moreover, this drive part is connected to the control part 18 (refer FIG. 1) provided in the appropriate place of the toilet device 1A through the signal line etc. similarly to the said 1st Embodiment, and operation control is made.

As shown in FIG. 6 (a), when the movable wall portion 19 is set to a water storage position in which the distal end portion is positioned above the base end portion, water can be stored up to the water storage level LV1. In this state, the tip of the movable wall portion 19 forms the trap top. Further, at this water storage position, the movable wall portion 19 is disposed in an inclined manner so as to rise toward the distal end side so as to constitute a wall portion of a general siphon-jet type trap portion 13A.
On the other hand, as shown in FIG. 6 (b), if the movable wall portion 19 is set at a low water level position where the distal end portion is located below the base end portion, water can be stored up to the low water level LV2. Become. In this state, the base end portion of the movable wall portion 19 constitutes the trap top portion. Further, at this low water level position, the movable wall portion 19 is arranged in an inclined shape so as to descend toward the tip side.
Also in the present embodiment configured as described above, each basic operation example can be executed in substantially the same manner as in the first embodiment. That is, the movable wall portion 19 is displaced to a low water level position or a stored water position, and it is possible to supply cleaning water or sterilizing liquid in conjunction with this.

In each of the above embodiments, the water level variable mechanisms 13 and 19 that can maintain the water level of the bowl portions 10 and 10A at the low water level LV2 lower than the accumulated water level LV1 are shown. The water level variable mechanisms 13 and 19 may not be provided. In this case, for example, the sterilizing liquid may be supplied in a state where the water level of the bowl portions 10 and 10A is lower than the accumulated water level LV1 due to the siphon phenomenon of the fixed trap portion. In this case, the supply of the sterilizing liquid may be continued until the stored water level LV1, or after supplying the sterilizing liquid, the cleaning water is supplied to set the stored water level LV1. Good. Further, the present invention is not limited to a mode in which the sterilizing liquid is supplied in a state in which the water level of the bowl portions 10 and 10A is lower than the stored water level LV1, but may be a mode in which the sterilizing liquid is supplied at the stored water level LV1. Various other modifications are possible for the supply timing of the sterilizing liquid.
Moreover, you may make it apply the structure which is mutually different in each above-mentioned embodiment by rearranging or combining suitably. In addition, different operations in the basic operation examples described above may be applied by appropriately rearranging or combining them.

1,1A Toilet device 10,10A Bowl part 13 Trap part (water level variable mechanism)
18 Control part 19 Movable wall part (water level variable mechanism)
20 Washing water supply part 26 Sterilization liquid supply part LV1 Reservoir level LV2 Low water level

Claims (3)

  A cleaning water supply unit that supplies cleaning water along the inner surface of the bowl part, a sterilizing liquid supply unit that supplies a sterilizing liquid having a smaller flow rate than the cleaning water along the inner surface of the bowl part, and a cleaning operation. And a controller that controls the sterilizing liquid supply unit to control the sterilizing liquid supply unit after the cleaning water supply unit is controlled to supply the cleaning water. Toilet bowl device. In claim 1,
The toilet device according to claim 1, wherein the controller supplies the sterilizing liquid in a state in which a water level of the bowl portion is lower than a stored water level. In claim 2,
A water level variable mechanism capable of maintaining the water level of the bowl portion at a low water level lower than the stored water level;
The toilet device according to claim 1, wherein the controller controls the sterilizing liquid supply unit and the water level variable mechanism so that the supply of the sterilizing liquid is continued from the low water level so as to reach the stored water level.

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