JP7029658B2 - bathroom - Google Patents

Description

The present invention relates to a bathroom.

A disinfectant water discharge device that discharges disinfectant water toward the washing floor of a bathroom is known (Patent Document 1). It is also known that in such a disinfectant water discharge device, electrolyzed water such as hypochlorite water generated by electrolyzing the flowing water (tap water) is used as the disinfectant water to be discharged. Has been done. By using such electrolyzed water as sterilized water, it is not necessary to prepare or replace a cartridge or the like for storing detergent or the like, as compared with the case of using detergent or the like, and it is very convenient to use.

In addition, in general, the user discharges the disinfected water toward the drain port by opening the drain plug of the bathtub and executing the disinfectant water start command after the bathroom use act such as bathing is completed. It is something that makes you.

Japanese Unexamined Patent Publication No. 2009-178470 Japanese Patent No. 3886055

A water seal is formed inside the drainage port. Dirt that easily floats on the water surface, such as sebum, comes into contact with and adheres to the line (water-sealing line) where the water surface of the sealed water and the drain trap that forms the sealed water are in contact, and bacteria easily propagate using this as a nutrient source. In addition, the sealing line is a part where water, nutrients, and air necessary for the growth of mold and fungi are prepared. Therefore, darkening is likely to occur on the water sealing line.

Focusing on this problem, the applicant wanted to apply sterilized water to the sealing line formed inside the drainage port to suppress the occurrence of darkening.

However, as described above, when electrolyzed water such as hypochlorite water is used as sterilized water, the electrolyzed water sterilizes when it comes into contact with the bacteria and returns to water, so that it flows in from the opening of the drain port. Before the electrolyzed water reaches the sealing line, the concentration of the disinfectant component of the electrolyzed water decreases. Therefore, there has been a problem that the occurrence of darkening in the water sealing line cannot be appropriately suppressed.

An object of the present invention is to provide a bathroom capable of suppressing the occurrence of darkening in a water sealing line.

The bathroom of the first invention has a sterilization action toward the tub, the drain plug provided in the tub, the drain trap installed below the drain port formed on the washing place floor, and the drain trap. An electrolytic water discharge device capable of discharging electrolytic water, a control unit that executes control to discharge electrolytic water when an execution command for discharging electrolytic water is received, and an operation of transmitting the execution command to the control unit by the user's operation. The drain trap is a bathroom provided with a section, and the inside of the main body of the drain trap is divided into two chambers, an inflow chamber and an outflow chamber, by a shielding member hung from the top surface, and the inside of the drain trap is on the top surface of the inflow chamber. An opening for inflow of drainage from the washing place floor is provided, a communication portion between the inflow chamber and the outflow chamber is provided at a portion submerged in the sealing water between the shielding member and the bottom surface of the main body, and an outflow outlet is provided in the outflow chamber. A tub drainage inflow port into which tub drainage flows is provided on the side surface of the inflow chamber, and the tub drainage collides with the shielding member to generate a vortex in the inflow chamber. After receiving the execution command, the control is executed so that the electrolytic water is not discharged until a predetermined time elapses, but the electrolytic water is discharged after the predetermined time has elapsed.
According to the first invention, after the user has completed bathing and other activities of using the bathroom, the drain plug of the bathtub is opened, and when the operation unit is operated, the electrolyzed water is intentionally discharged until a predetermined time elapses. Instead, the electrolyzed water is discharged after the predetermined time has elapsed.
When the drain plug of the bathtub is opened, the drainage of the bathtub collides with the shielding member, and a vortex is generated in the inflow chamber. The water level of the water sealing line that is in contact with the water rises. As a result, sebum and hair adhering to the inner wall inside the drainage port above the actual water sealing line can be washed away.
Therefore, it is possible to prevent the concentration of the sterilizing component of the electrolyzed water from decreasing due to contact with the sebum adhering to the inner wall inside the drainage port before reaching the original sealing line where darkening is likely to occur. That is, the electrolyzed water can flow into the sealing line inside the drainage port without reducing the concentration of the sterilizing component. Therefore, even when the electrolyzed water is used as sterilized water, it is possible to appropriately suppress the occurrence of darkening in the water sealing line.
The second invention is characterized in that, in the first invention, the operation unit transmits the execution command to the control unit by the operation of the user, and at the same time, opens the drain plug of the bathtub. ..
According to the second invention, after the sebum and hair adhering to the inner wall inside the drainage port above the water sealing line are surely washed away by the vortex flow, the electrolyzed water can flow toward the drainage port. can. As a result, the electrolyzed water in which the decrease in the concentration of the sterilizing component is suppressed can be reliably flowed into the sealing line.
According to the third aspect of the invention, in the first or second invention, the predetermined time is a length of 300 seconds or more, which is the time from the start of the discharge of the bathtub water to the completion of the discharge, which is the time equivalent to the discharge of the bathtub water. It is characterized by being a water.
According to the third invention, after the drainage of the bathtub water is completed, that is, after the temporary rise in the water level due to the generation of the vortex in the drain trap is completed (after the vortex disappears), the drain trap Electrolyzed water can flow into the inside. As a result, the waste of the electrolyzed water discharged together with the vortex flow can be eliminated, and the electrolyzed water can be surely flowed into the original sealing line.
In the fourth aspect of the invention, in any one of the first to third inventions, tap water other than electrolyzed water is discharged toward the drain port until the predetermined time elapses, and the predetermined time elapses. It is characterized in that the electrolyzed water is discharged after the operation.
According to the fourth invention, by generating a vortex in the inflow chamber by discharging the bathtub water, it is possible to wash away sebum and hair adhering to the inner wall inside the drainage port above the actual water sealing line. Since the vortex is a sealed water formed by sewage, the sewage may still adhere to the inner wall inside the drainage port even after the vortex generation is completed. Therefore, by discharging tap water other than electrolyzed water until a predetermined time elapses, the inner wall inside the drainage port can be washed away.
According to the fifth aspect of the present invention, the tap water that is not electrolyzed water has a length of 300 seconds or more, which is the time from the start of the discharge of the bathtub water to the completion of the discharge, which is the time equivalent to the discharge of the bathtub water. Now, it is characterized in that it is discharged toward the drain port.
According to the fifth invention, after the generation of the eddy current is completed, tap water other than electrolyzed water can be discharged, and the inner wall inside the drainage port can be washed away more reliably.
A sixth aspect of the invention is characterized in that, in any one of the first to third inventions, tap water, which is not electrolyzed water, is discharged toward the washing place floor until the predetermined time elapses. ..
According to the sixth invention, while a vortex is being generated in the inflow chamber of the drain trap, the sebum stains on the floor surface of the washing place can be washed away with tap water, and then the electrolyzed water can be discharged. Therefore, by washing away the sebum stains on the floor surface of the washing place with tap water in advance, it is possible to suppress the possibility that the sebum stains on the floor surface of the washing place flow into the drainage port after the discharge of the electrolyzed water is started.
According to the sixth aspect of the invention, the tap water, which is not electrolyzed water, has a length of 300 seconds or more, which is the time from the start of discharge of the bathtub water to the completion of the discharge, which is the time equivalent to the discharge of the bathtub water. Now, it is characterized in that it is discharged toward the drain port.
According to the seventh invention, tap water that is not electrolyzed water can be discharged until after the vortex generation is completed, and the tap water that has washed the washing floor is used to more reliably clean the inner wall inside the drain port. Can be washed away.

According to the bathroom of the present invention, a bathroom capable of suppressing the occurrence of darkening in the water sealing line is provided.

The system block diagram which shows the whole structure of the bathroom cleaning apparatus which concerns on embodiment. The schematic perspective view of the bathroom which concerns on embodiment. The plan view of the bathtub which concerns on embodiment. The perspective view of the water discharge part which concerns on embodiment. (A) is a schematic perspective view of the drain trap according to the embodiment, and (b) is a schematic cross-sectional view of the drain trap. (A) is a discharge time chart of electrolyzed water in the embodiment, and (b) is a discharge time chart of tap water and electrolyzed water in the embodiment. Schematic cross-sectional view for explaining the generation of a vortex in a drain trap and the inflow of electrolyzed water in an embodiment. Schematic cross-sectional view for explaining the generation of a vortex in a drain trap and the inflow of tap water in an embodiment. Schematic cross-sectional view for explaining the inflow of tap water and electrolyzed water into a drain trap according to an embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. In order to facilitate understanding of the description, the same components are designated by the same reference numerals as possible in the drawings, and duplicate description is omitted.

FIG. 1 is a system block diagram showing the overall configuration of the bathroom cleaning device 1 according to the embodiment.

The bathroom cleaning device 1 includes a power supply 30, a control unit 40, an operation unit 35, and an electrolyzed water discharge device 100. The electrolyzed water discharge device 100 is installed at the counter in the bathroom.

FIG. 2A is a schematic perspective view of the bathroom 500 according to the embodiment.
FIG. 2B is an enlarged schematic perspective view of the vicinity of the counter 530 in the bathroom 500.
FIG. 3 is a plan view of the bathtub 510.

As shown in FIG. 2A, the bathroom 500 is surrounded by four walls 541-544 and a ceiling 545. A bathtub 510, a washing floor 520, and a counter 530 are provided in the bathroom 500. Further, the bathroom 500 is appropriately provided with a mirror, a faucet device, a hand shower and the like.

A first wall 541 and a second wall 542 are provided on the pair of short sides of the bathtub 510 so as to face each other. A fourth wall 544 is provided on one long side of the bathtub 510. A third wall 543 is provided on the washing floor 520 side facing the fourth wall 544.

A drainage port 521 is provided on the washing floor 520. In the example shown in FIG. 2A, the drainage port 521 is located near the edge of the washroom floor 520 on the bathtub 510 side and is located substantially in the center of the washroom floor 520 in the longitudinal direction.

On the surface (floor surface) of the washing place floor 520, from the edge on the first wall 541 side, the edge on the second wall 542 side, and the edge on the third wall 543 side, toward the drainage port 521. A gentle downward slope (drainage slope) is provided.

The counter 530 is attached to, for example, a second wall 542. The counter 530 is installed so as to be separated upward from the surface of the washing floor 520. The counter 530 has a substantially rectangular shape having a long side along the short side direction of the washing place floor 520 when viewed from above.

As shown in FIG. 2B, the counter 530 has a top plate 531 and a cover 532 that covers the lower part of the top plate 531. The electrolyzed water discharge device 100 shown in FIG. 1 is housed inside a counter 530 surrounded by a top plate 531 and a cover 532, except for some elements (water stop plug 50, water discharge unit 10).

As shown in FIG. 2B, the water discharge portion (nozzle portion) 10 is provided so as to project below the counter 530. The water spouting portion 10 is separated from the surface of the washing place floor 520. Further, the water discharge portion 10 is installed near the center of the counter 530 in the lateral width direction (short direction). That is, the water discharge portion 10 is installed on one end side in the longitudinal direction of the washing place floor 520 and near the center in the short side direction. By the rotational operation of the water discharge unit 10 described later at this position, tap water and electrolyzed water can be easily discharged to substantially the entire washing place floor 520.

As shown in FIG. 3, a drain plug 511 is provided on the bottom surface of the bathtub 510. The drain plug 511 opens and closes the bathtub drain port formed on the bottom surface of the bathtub 510. A drain plug button 512 is provided on the rim of the bathtub 510, and the drain plug 511 is opened and closed by operating the drain plug button 512.

The water stop valve 50 shown in FIG. 1 is connected to a water supply pipe to which tap water is supplied. The water stop valve 50 is connected to the strainer 51. The downstream side of the strainer 51 is connected to the constant flow rate valve 52, and the downstream side of the constant flow rate valve 52 is branched into two pipes 61 and 62.

A solenoid valve 53 is provided in one of the pipes 61, and the downstream side of the solenoid valve 53 is connected to the first water discharge port 11 of the water discharge unit 10. Further, for example, in a cold region, a drain valve 54 is connected between the solenoid valve 53 and the water discharge unit 10 as needed.

The strainer 55, the solenoid valve 56, the pressure regulating valve 57, the check valve 59, the electrolyzed water generating section 20, the strainer 65, and the second spout 12 of the spouting section 10 are connected to the other pipe 62 in this order from the upstream side. Has been done. Further, a safety valve 58 is connected between the pressure regulating valve 57 and the check valve 59.

Further, the electrolyzed water discharge device 100 has a motor (for example, a stepping motor) 66 that rotates (turns) the water discharge unit 10. This motor 66 is also housed inside the counter 530.

The control unit 40 controls the operations of the solenoid valve 53, the solenoid valve 56, the electrolyzed water generation unit 20, and the motor 66. The power source 30 supplies power to them. Further, the power supply 30 supplies electric power to the operation unit 35. As shown in FIG. 2A, the power supply 30 is installed, for example, behind the ceiling 545 of the bathroom 500. The control unit 40 is installed inside the counter 530 or behind the ceiling 545 of the bathroom 500.

The solenoid valve 53 is opened and closed under the control of the control unit 40. When the solenoid valve 53 is opened, tap water is discharged from the first spout port 11. When the solenoid valve 53 is closed, tap water is not discharged from the first spout port 11.

The solenoid valve 56 is opened and closed under the control of the control unit 40. When the electromagnetic valve 56 is opened, tap water is supplied to the electrolyzed water generation unit 20, and the electrolyzed water generated by the electrolyzed water generation unit 20 is discharged from the second spout 12. When the solenoid valve 56 is closed, the electrolyzed water is not discharged from the second spout port 12.

The flow rate of tap water supplied to the electrolyzed water generation unit 20 is adjusted by controlling the pressure of tap water by the pressure regulating valve 57. By adjusting the flow rate of tap water supplied to the electrolyzed water generation unit 20, the flow rate of the electrolyzed water discharged from the second spout 12 is adjusted.

Further, the flow rate of tap water supplied to the downstream side thereof can be adjusted by the solenoid valves 53 and 56.

The electrolyzed water generation unit 20 generates electrolyzed water. This electrolyzed water is sterilizing water having a sterilizing action. The electrolyzed water generation unit 20 is, for example, an electrolytic cell having an anode and a cathode. By applying a voltage between the anode and the cathode to electrolyze the tap water flowing between the anode and the cathode, the tap water is transformed into electrolyzed water. Since tap water contains chloride ions, hypochlorous acid is produced by electrolyzing the chloride ions.

Hypochlorous acid has the ability to kill bacteria and suppress the growth of bacteria. Therefore, the electrolyzed water is sterilized water containing hypochlorous acid and having a sterilizing action.

FIG. 4 is a perspective view of the water discharge portion 10.

The water spouting portion 10 is formed in a cylindrical shape, and a first spouting port 11 and a second spouting port 12 are provided on the lower side surface thereof. The first spout 11 and the second spout 12 are each formed in a vertically long slit shape.

The first spout 11 and the second spout 12 are arranged side by side in the circumferential direction of the cylindrical spout portion 10. Alternatively, the first spout 11 and the second spout 12 may be arranged side by side in the height direction.

From the first spout 11, tap water that is not electrolyzed water is spouted to the washing place floor 520. From the second spout 12, the above-mentioned electrolyzed water (sterilized water) is discharged to the washing place floor 520. Tap water or electrolyzed water can be temporarily stored in the cylindrical water discharge portion 10, and the water discharge pressure can be increased.

Tap water spread in a fan shape in the vertical direction (vertical direction) can be discharged from the vertically long first spout port 11. Similarly, the electrolyzed water spread in a fan shape in the vertical direction (vertical direction) can be discharged from the vertically long second spout port 12.

By driving the motor 66 described above, the cylindrical water discharge portion 10 can be rotated around its central axis (indicated by the alternate long and short dash line in FIG. 4) to change the direction in which tap water or electrolyzed water is discharged. ..

5 (a) is a schematic perspective view of the drain trap 70 according to the embodiment, and FIG. 5 (b) is a schematic cross-sectional view of the drain trap 70.

The drain trap 70 is installed below the drain port 521 formed on the washing floor 520. A drainage basin 91 is integrally formed in a concave shape on the washing floor 520, and a drainage trap 70 is connected to the lower part of the drainage basin 91. The upper surface of the drainage basin 91 is covered with the drainage cover 95 shown in FIG. 2A.

A flange member 92 is attached to the bottom side of the drainage basin 91 via packing, and the upper end of the drainage trap 70 is attached to the flange member 92. A hair catcher 81 is detachably attached to the inside of the flange member 92 from above.

Above the main body 80 of the drain trap 70, an opening 93 for inflow of drainage from the washing place is provided. The drainage from the washing place floor 520 side passes through the drainage basin 91 and flows into the drainage trap 70 from the opening 93.

A bathtub drainage inlet 78 is formed on the side surface of the main body 80 of the drain trap 70. The bathtub drainage inlet 78 is connected to the bathtub drainage port through a pipe connected to the bathtub drainage inlet 78.

An outlet 79 is formed on the opposite side of the bathtub drainage inlet 78. The bathtub drainage, washing place drainage, electrolyzed water, etc. that have flowed into the drain trap 70 flow out to the drain pipe connected to the outlet 79 through the outlet 79.

On the upstream side of the outflow port 79, a water sealing wall 77 integrally raised from the bottom surface 72 of the main body 80 is formed. The upper end of the water sealing wall 77 is the height of the water sealing surface W.

On the upstream side of the sealing wall 77, a shielding member 76 is provided so as to vertically suspend the inside of the main body 80 of the drain trap 70 from the top surface 71. The shielding member 76 divides the inside of the drain trap 70 into two chambers, an inflow chamber 73 and an outflow chamber 74. A communication portion 75 for communicating the inflow chamber 73 and the outflow chamber 74 is formed between the lower end of the shielding member 76 and the bottom surface 72 of the drain trap 70. The communication portion 75 is provided at a portion submerged in water between the shielding member 76 and the bottom surface 72.

A bathtub drainage inlet 78 is formed on the side surface of the inflow chamber 73, and the bathtub drainage inlet 78 communicates with the inflow chamber 73. An outlet 79 is formed on the side substantially opposite to the bathtub drainage inlet 78, and the outlet 79 communicates with the outflow chamber 74. An opening 93 for drainage from the washing place is formed on the top surface (upper side) of the inflow chamber 73.

The drain trap 70 is configured to generate a vortex in the inflow chamber 73 when the bathtub drainage flowing from the bathtub drainage inlet 78 collides with the shielding member 76. The bathtub drainage that has flowed into the inflow chamber 73 swirls along the inner peripheral surface of the drain trap 70 and the shielding member 76 to form a vortex flow. Since the shielding member 76 is inclined in an enlarged diameter from the lower end side toward the upper side, this vortex is guided by the shielding member 76 to become an ascending vortex and ascends in the main body 80.

If the inclination angle of the shielding member 76 is set so that the rising vortex flows up to the vicinity of the upper end of the drainage basin 91, dust and hair adhering to the inner peripheral surface of the drainage basin 91 and the hair catcher 81 due to the rising vortex flow. Is dropped, collected in the center of the vortex, and further dropped downward from the center of the vortex, and dust and hair are collected in the center of the bottom surface of the lower end of the hair catcher 81. As a result, the hair catcher 81 is kept in a state in which no hair or the like adheres to the hair catcher 81 other than the central portion thereof, and the water flow is improved.

FIG. 6A is a discharge time chart of electrolyzed water according to the embodiment.

When the user operates the operation unit 35 described above (when the operation unit 35 is turned on), the operation unit 35 transmits an execution command for discharging electrolyzed water to the control unit 40. After receiving the execution command for discharging the electrolyzed water from the operation unit 35, the control unit 40 does not discharge the electrolyzed water until a predetermined time elapses, and executes control so that the electrolyzed water is discharged after the predetermined time has elapsed. ..

That is, when the user operates the drain plug button 512 shown in FIG. 3 to open the drain plug 511 of the bathtub 510 and operates the operation unit 35 after the user completes the action of using the bathroom such as bathing, he / she dares to operate the operation unit 35 for a predetermined time. The electrolyzed water is not discharged until the elapse, and the electrolyzed water is discharged after the predetermined time has elapsed.

7 (a) to 7 (c) are schematic cross-sectional views for explaining the generation of a vortex flow in the drain trap 70 and the inflow of electrolyzed water in the embodiment.

FIG. 7A shows a state in which the drain plug 511 of the bathtub 510 is closed and the bathtub drainage does not flow into the drain trap 70. Then, when the drain plug 511 of the bathtub 510 is opened, the bathtub drainage flowing from the bathtub drainage inlet 78 collides with the shielding member 76, and a vortex is generated in the inflow chamber 73. As shown in FIG. 7B, the vortex causes centrifugal force to be generated in the sealed water, and the water level W'of the sealing line where the drain trap 70 and the sealing water are in contact with each other temporarily rises. As a result, sebum and hair adhering to the inner wall inside the drainage port 521 (the inner wall of the drainage basin 91 and the inner wall of the drain trap 70) above the actual water sealing line W defined by the height of the water sealing wall 77. Etc. can be washed away.

Then, after a predetermined time has elapsed from the operation of the operation unit 35, the control unit 40 discharges the electrolyzed water from the water discharge unit 10 toward the drain port 521, and the electrolyzed water is drained as shown in FIG. 7 (c). It flows into the drain trap 70 from the mouth 521.

Due to the rise in water level accompanying the generation of the vortex, sebum and the like on the route until the electrolyzed water flowing in from the drainage port 521 reaches the original sealing line W are washed away. Therefore, it is possible to prevent the concentration of the sterilizing component of the electrolyzed water from decreasing due to contact with the sebum adhering to the inner wall inside the drainage port 521 before reaching the original sealing line W where darkening is likely to occur. That is, the electrolyzed water can flow into the sealing line W inside the drain port 521 (drain trap 70) without reducing the concentration of the sterilizing component. Therefore, even when the electrolyzed water is used as the sterilized water, the occurrence of darkening in the water sealing line W can be appropriately suppressed.

Here, for a predetermined time, when the bathtub of a general size is almost full, for example, the bathtub water is discharged from the state where the bathtub water is stored up to 90% of the allowable water level of the bathtub, and the bathtub water is discharged from the start of the discharge. The length is 300 seconds or more, which is the time required to complete the bathtub water discharge. After the lapse of this predetermined time, the electrolyzed water is continuously discharged for, for example, 390 seconds.

By setting the predetermined time to a length equal to or longer than the time equivalent to the discharge of the bathtub water, the water level temporarily rises after the discharge of the bathtub water is completed, that is, due to the generation of the vortex in the drain trap 70. After finishing (after the vortex flow disappears), the electrolyzed water can flow into the drain trap 70. As a result, the waste of the electrolyzed water discharged together with the vortex flow can be eliminated, and the electrolyzed water can be surely flowed into the original sealing line.

Further, the operation unit 35 can transmit the execution command of the electrolyzed water discharge to the control unit 40 by the operation of the user, and can also open the drain plug 511 of the bathtub 510. That is, when the operation unit 35 is operated by the user, not only the execution command for discharging the electrolyzed water is transmitted to the control unit 40, but also the drain plug 511 of the bathtub 510 is opened.

Even if the user does not operate the drain plug button 512, the electrolyzed water is discharged after the predetermined time has elapsed after the drain plug 511 of the bathtub 510 is opened more reliably in conjunction with the operation of the operation unit 35. Discharge toward the drain port 521. That is, the electrolyzed water can flow toward the drainage port 521 after the sebum and hair adhering to the inner wall of the drainage port 521 above the water sealing line are surely washed away by the vortex flow. As a result, the electrolyzed water in which the decrease in the concentration of the sterilizing component is suppressed can be reliably flowed into the sealing line.

FIG. 6B is a discharge time chart of tap water and electrolyzed water in another embodiment.
8 (a) to 9 (b) are schematic cross-sectional views for explaining the actions of the sealed water, tap water, and electrolyzed water in the drain trap according to the time chart shown in FIG. 6 (b). ..

In this example, when the control unit 40 receives the execution command, the control unit 40 discharges tap water, which is not electrolyzed water, toward the drain port 521 until a predetermined time elapses. Then, after receiving the above execution command and elapsed for a predetermined time (during which tap water is discharged), the electrolyzed water is discharged.

FIG. 8A shows a state in which the drain plug 511 of the bathtub 510 is closed and the bathtub drainage does not flow into the drain trap 70. Then, when the drain plug 511 of the bathtub 510 is opened, as shown in FIG. 8B, the bathtub drainage flowing from the bathtub drainage inlet 78 collides with the shielding member 76, and a vortex is generated in the inflow chamber 73. do.

By generating a vortex in the inflow chamber 73 by discharging the bathtub water, it is possible to wash away the sebum and hair adhering to the inner wall inside the drainage port 521 above the actual water sealing line, but the vortex is sewage. Since the water is sealed, the sewage can still be attached to the inner wall of the drainage basin 91 or the drainage trap 70 even after the vortex generation is completed. Therefore, the inner walls of the drainage basin 91 and the drainage trap 70 can be washed away by discharging tap water that is not electrolyzed water until a predetermined time elapses.

The tap water, which is not electrolyzed water, is discharged toward the drain port 521 with a length of 300 seconds or more, which is the time equivalent to the discharge of bathtub water described above. For example, when the operation unit 35 is turned on, tap water is intermittently discharged. In the example shown in FIG. 6B, tap water is intermittently discharged twice in 480 seconds. For example, 240 seconds after the end of tap water discharge, the electrolyzed water is continuously discharged for 390 seconds.

By discharging tap water for a length equivalent to or longer than the bathtub water discharge, as shown in FIG. 9A, the inner wall inside the drain port 521 is surely washed away with tap water after the vortex generation is completed. Can be done. After that, as shown in FIG. 9B, the electrolyzed water in which the decrease in the concentration of the sterilizing component is suppressed flows into the drain trap 70 from the drain port 521.

Further, the water discharge unit 10 discharges tap water, which is not electrolyzed water, toward the washing place floor 520 until the predetermined time elapses. That is, while the vortex is being generated in the inflow chamber 73 of the drain trap 70, the sebum stains on the surface of the washing place floor 520 can be washed away with tap water, and then the electrolyzed water can be discharged. Therefore, by washing away the sebum stains on the surface of the washing place floor 520 with tap water in advance, there is a possibility that the sebum stains on the surface of the washing place floor 520 may flow into the drain port 521 after the discharge of the electrolyzed water is started. Can be suppressed.

The tap water is discharged for a length of 300 seconds or more, which is the time equivalent to the discharge of bathtub water described above. As a result, as shown in FIG. 9A, tap water that is not electrolyzed water can be discharged until after the vortex generation is completed, and tap water that has washed the washing floor 520 can be used more reliably. The inner wall inside the drain port 521 can be washed away.

In the present embodiment, for example, the discharge flow rate of the electrolyzed water from the water discharge unit 10 is 9 (m / s) or more and 11 (m / s) or less, and the discharge flow rate of tap water from the water discharge unit 10 is 5.6 (. m / s).

In addition, electrolyzed water and tap water are each discharged in granular form. For example, the particle size of electrolyzed water is 800 (μm), and the particle size of tap water is 0.3 (mm) or more and 3.5 (mm) or less.

The embodiments of the present invention have been described above with reference to specific examples. However, the present invention is not limited to these, and various modifications can be made based on the technical idea of the present invention.

1 ... Bathroom cleaning device, 10 ... Water discharge unit, 20 ... Electrolytic water generation unit, 35 ... Operation unit, 40 ... Control unit, 70 ... Drain trap, 73 ... Inflow chamber, 74 ... Outflow chamber, 75 ... Communication unit, 76 ... Shielding member, 77 ... Sealed wall, 78 ... Bath drainage inlet, 79 ... Outlet, 91 ... Drainage basin, 93 ... Opening, 100 ... Electrolyzed water discharge device, 510 ... Bathtub, 511 ... Drainage plug, 520 ... Washroom floor 521 ... Drainage outlet

Claims (7)

Electrolyzed water or water that has a sterilizing effect on the drain trap through the bath, the drain plug provided in the bath, the drain trap installed below the drain port formed on the washing place floor, and the drain port. An electrolyzed water discharge device that can discharge the electrolyzed water or tap water to the washing place floor so that water flows in, a control unit that executes control to discharge the electrolyzed water when an execution command for discharging the electrolyzed water is received, and a user. A bathroom provided with an operation unit that transmits the execution command to the control unit by the operation of.
The drain trap is
The main body is divided into two chambers, an inflow chamber and an outflow chamber, by a shielding member suspended from the top surface.
An opening for inflow of floor drainage from the washing area is provided on the top surface of the inflow chamber.
A communication portion between the inflow chamber and the outflow chamber is provided at a portion submerged in the sealing water between the shielding member and the bottom surface of the main body.
An outlet is provided in the outflow chamber.
A bathtub drainage inlet is provided on the side surface of the inflow chamber to allow bathtub drainage to flow in.
The bathtub drainage collides with the shielding member to generate a vortex in the inflow chamber.
When the user operates the operation unit, the drain plug of the bathtub is opened, and the control unit does not discharge the electrolyzed water until a predetermined time elapses after receiving the execution command. A bathroom characterized in that control is performed so that electrolyzed water is discharged after the lapse of a predetermined time. The bathroom according to claim 1, wherein the operation unit transmits the execution command to the control unit by the operation of the user and opens the drain plug of the bathtub. The predetermined time is the length of 300 seconds or more, which is the time from the start of discharge of the bathtub water to the completion of the discharge of the bathtub water, which is the time equivalent to the discharge of the bathtub water, according to claim 1 or 2. bathroom. The claim is characterized in that tap water, which is not electrolyzed water, is discharged to the washing place floor so as to flow into the drainage port until the predetermined time elapses, and the electrolyzed water is discharged after the elapse of the predetermined time. The bathroom described in 3 . For tap water that is not electrolyzed water, the time from the start of discharge to the end of discharge is 300 seconds or more, which is the estimated time from the start of discharge to the completion of discharge of bathtub water. The bathroom according to claim 4, wherein the bathroom is discharged to the washing place floor so as to flow into the drain port. The bathroom according to claim 3 , wherein tap water, which is not electrolyzed water, is discharged to the washing place floor so as to flow into the drainage port until the predetermined time elapses. Tap water that is not electrolyzed water is discharged toward the drain port for a length of 300 seconds or more, which is the time from the start of discharge of bath water to the completion of discharge, which is the time equivalent to the discharge of bath water. The bathroom according to claim 6, wherein the bathroom is characterized in that.

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