JP2008174944A - Water closet - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a water closet which can secure the quantity of flushing water required for locking communication between a drain trap pipeline and a bowl even during a power failure. <P>SOLUTION: This water closet comprises: a toilet bowl body 2 which is provided with the bowl 12, a rim water-ejection port 18 and a jet water ejection port 16 for ejecting the flushing water, and the drain trap pipeline 14; a water storage tank 32 for storing the flushing water; and a flushing water supply means 40 which supplies the flushing water to the rim water-ejection port, supplies the flushing water to the jet water ejection port by resupplying the flushing water to the water storage tank, and is driven by electric power supplied from a power source. The flushing water supply means is equipped with a pressure pump 34 which supplies the flushing water stored in the water storage tank to the jet water ejection port by pressurizing the flushing water. On the occurrence of the power failure during the operation of the pressure pump, the pressure pump supplies the jet water ejection port with the flushing water in quantities (Q1+Q2) required for locking communication between the drain trap pipeline and the bowl by the rotation of its rotating portions 52 (48, 46a and 50a) by an inertial force. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a flush toilet, and more particularly to a flush toilet that is washed with pressurized flush water.

  Conventionally, as described in Patent Document 1, rim water discharge causes tap water to be discharged directly from the rim water discharge port, while jet water discharge uses washing water stored in a tank housed in the toilet body. There has been known a flush toilet in which a bowl portion is washed by pressurizing with a pump and discharging the pressurized wash water from a jet spout.

Japanese Patent No. 2800421

  The flush toilet described in the above-mentioned Patent Document 1 is not affected by fluctuations in tap water pressure because the flush water stored in the tank is pressurized with a pump and discharged from the jet spout. There is an advantage that it can be used in low water pressure areas and places.

  However, in a flush toilet that supplies wash water by a pump that is operated by electric power supplied from a power source as described in Patent Document 1 described above, a draining trump conduit is operating while the pump is operating, that is, by siphon action. In the unlikely event that power is interrupted when filth is being discharged from the pump, the jet water discharged by the pump is immediately stopped, so the cleaning water required to seal the communication between the drain trap line and the bowl The situation is such that the amount of (sealed water) cannot be secured. In this case, there arises a problem that the sewage pipe to which the drain trap pipe is connected communicates with the bowl portion of the toilet bowl, and bad odor enters the toilet bowl. This problem is an important problem that must be solved when commercializing flush toilets.

  Therefore, the present invention has been made to solve the above-described problems, and even in the event of a power failure, the cleaning water (sealing) required for sealing the communication between the drain trap pipe and the bowl portion. The purpose of the present invention is to provide a flush toilet that can secure the amount of water.

In order to solve the above-described problems, the present invention is a flush toilet that is washed with pressurized wash water, and includes a bowl portion, a rim spout and a jet spout for discharging wash water, and a drain trap pipe. A toilet body provided with a road, a water storage tank for storing cleaning water, and a cleaning water supply means for supplying the cleaning water to the rim outlet and supplying the water to the jet outlet. Water supply means driven by electric power supplied from a power source, and the wash water supply means pressurizes the wash water stored in the water storage tank and applies pressure to the jet water outlet The pressure pump is equipped with a pump, and in the event of a power failure during its operation, the amount of flush water required to seal the communication between the drain trap pipe and the bowl portion by the rotation of the inertial force of the rotating portion. The jet spout It is characterized by being configured to feed.
In the present invention configured as described above, when the pressure pump is operated and the washing water stored in the water storage tank is pressurized and supplied to the jet spout, it is a case where a power failure occurs. In addition, it is possible to supply a necessary amount of washing water to the jet water outlet by the rotation by the inertial force of the rotating part of the pressurizing pump, thereby sealing the communication between the drain trap pipe and the bowl part.

In the present invention, preferably, the pressurizing pump can seal the communication between the drain trap pipe and the bowl part by at least the amount of washing water supplied by the rotation by the inertial force of the rotating part. The inertia force of the rotating part is set.
In the present invention configured as described above, it is possible to supply at least an amount of cleaning water capable of sealing the communication between the drain trap pipe and the bowl portion by the rotation by the inertial force of the rotating portion of the pressurizing pump. Therefore, the communication between the drain trap pipe and the bowl portion can be sealed even during a power failure.

In the present invention, it is preferable that the pressurizing pump has a drain trap line by a sum of an amount of wash water supplied by rotation by an inertial force of the rotating part and an amount of return wash water in the drain trap pipe. The inertial force of the rotating part is set so that the communication with the bowl part can be sealed.
In the present invention configured as described above, the drain trap pipe is calculated based on the sum of the amount of the wash water supplied by the rotation of the rotating portion of the pressurizing pump and the amount of the return wash water in the drain trap pipe. The communication between the path and the bowl portion can be sealed.

  In the present invention, preferably, the amount of washing water required to seal the communication between the drain trap pipe and the bowl portion is an amount in the range of 700 cc to 1300 cc.

  According to the flush toilet of the present invention, even during a power failure, the amount of washing water (sealed water) necessary to seal the communication between the drain trap pipe and the bowl portion can be secured, As a result, bad smell can be prevented from entering the toilet from the sewer pipe.

Next, a flush toilet according to an embodiment of the present invention will be described with reference to the accompanying drawings.
First, the structure of a flush toilet according to an embodiment of the present invention will be described with reference to FIGS. Here, FIG. 1 is a side view of a flush toilet according to an embodiment of the present invention, FIG. 2 is a plan view of the flush toilet shown in FIG. 1, and FIG. 3 is a flush toilet according to an embodiment of the present invention. FIG. 4 is a partial cross-sectional view showing a pressurizing pump used in a flush toilet according to an embodiment of the present invention.

  As shown in FIGS. 1 and 2, the flush toilet 1 according to the embodiment of the present invention is disposed so as to cover the toilet body 2, the toilet seat 4 disposed on the upper surface of the toilet body 2, and the toilet seat 4. The cover 6 and the local washing | cleaning apparatus 8 arrange | positioned at the back upper part of the toilet bowl main body 2 are provided. Furthermore, a functional unit 10 is disposed behind the toilet body 2, and the functional unit 10 is covered with a side panel 10a.

The toilet body 2 is formed with a bowl portion 12 for receiving filth, a drain trap pipe 14 extending from the bottom of the bowl portion 12, a jet spout 16 for jet spout, and a rim spout 18 for rim spout. ing.
The jet spout 16 is formed at the bottom of the bowl portion 12, is disposed substantially horizontally toward the inlet of the drain trap pipe 14, and discharges wash water toward the drain trap pipe 14. ing.
The rim water spouting port 18 is formed at the upper left rear of the bowl portion 12 and discharges cleaning water along the edge of the bowl portion 12.

  The drain trap pipe 14 includes an inlet 14a, a trap ascending pipe 14b rising from the inlet 14a, and a trap descending pipe 14c descending from the trap ascending pipe 14b. The trap ascending pipe 14b and the trap descending pipe 14c. 14d is the top portion 14d.

  The flush toilet 1 according to the present embodiment is directly connected to a water supply that supplies cleaning water, and the cleaning water is discharged from the rim spout 18 by the water supply pressure of the water supply. As for the jet water spouting, as will be described later, the washing water stored in the water storage tank 32 built in the functional unit 10 is pressurized by the pressurizing pump 34 and discharged from the jet water spouting port 16 at a large flow rate. It has become.

Next, the functional unit 10 of the flush toilet 1 according to the present embodiment will be described in detail with reference to FIG.
As shown in FIG. 3, the functional unit 10 is provided with a constant flow valve 20, an electromagnetic valve 22, a rim water discharge vacuum breaker 24, and a rim water discharge flapper valve 26. Further, the water supply channel 19 includes a switching valve 28 for switching between water supply to the tank and rim water discharge, a water storage tank 32, a pressure pump 34, a jet water discharge vacuum breaker 36, a jet water discharge flapper valve 38, water A stopper 39 is incorporated. The function unit 10 also includes a controller 40 that controls the opening / closing operation of the electromagnetic valve 22, the switching operation of the switching valve 28, and the rotation speed and operating time of the pressurizing pump 34.

  The constant flow valve 20 is for restricting the wash water flowing from the water inlet 20a through the stop cock 42a, the strainer 42b, and the branch fitting 42c to a predetermined flow rate or less. In the present embodiment, the constant flow valve 20 is configured to limit the flow rate of the cleaning water to 16 liters / minute or less. Further, the wash water that has passed through the constant flow valve 20 flows into the electromagnetic valve 22, and the wash water that has passed through the electromagnetic valve 22 is supplied to the rim water spouting port 18 or the water storage tank 32 by the switching valve 28. ing.

The electromagnetic valve 22 is opened and closed by a control signal from the controller 40 so that the supplied wash water flows into the switching valve 28 or is stopped.
The switching valve 28 is switched by a control signal from the controller 40, and the wash water that has flowed in via the electromagnetic valve 22 is discharged from the rim spout 18 or flows into the water storage tank 32.

  The rim water discharge vacuum breaker 24 is disposed in the middle of the rim-side water supply path 18 a that guides the wash water that has passed through the switching valve 28 to the rim water discharge port 18, and prevents backflow from the rim water discharge port 18 of the wash water. Further, the rim water spouting vacuum breaker 24 is disposed above the upper end surface of the bowl portion 12, thereby reliably preventing backflow. Further, the washing water overflowing from the air release portion of the rim water spouting vacuum breaker 24 flows into the water storage tank 32 through the return conduit 24a.

  The rim water spouting flapper valve 26 is disposed in the rim-side water supply passage 18 a downstream of the rim water spouting vacuum breaker 24, and prevents backflow from the rim water spouting port 18 of the cleaning water. In the present embodiment, the rim water discharge vacuum breaker 24 and the rim water discharge flapper valve 26 are arranged in series in the rim side water supply path 18a, thereby preventing the backflow of the washing water more reliably.

  The water storage tank 32 is configured to store cleaning water to be discharged from the jet water discharge port 16. In the present embodiment, the water storage tank 32 has an internal volume of about 2.5 liters.

  Furthermore, in this embodiment, the front-end | tip (lower end) of the tank water supply path 32a is opened to the position above the water storage tank 32, and the backflow from the water storage tank 32 to the tank water supply path 32a is prevented. Further, an upper end float switch 32b and a lower end float switch 32c are disposed inside the water storage tank 32 so that the water level in the water storage tank 32 can be detected. The upper end float switch 32b is turned on when the water level in the water storage tank 32 reaches a predetermined water storage level, and the controller 40 detects this and closes the electromagnetic valve 28. On the other hand, the lower end float switch 32c is turned on when the water level in the water storage tank 32 falls to a predetermined water level, and the controller 40 detects this and stops the pressurizing pump 34.

  A lid 32d is attached to the upper portion of the water storage tank 32 so as to cover the opening at the upper end thereof, and the outer periphery of the lid 32d and the inner wall surface of the upper portion of the water storage tank 32 are joined in a watertight manner. Yes. Furthermore, the lid 32d is provided with a circular hole, and a cylindrical body 32e is attached so as to extend upward so as to surround the hole.

  The wall surface 32g of the water storage tank 32 extends upward from the lid body 32d, and the wash water overflowing from the cylinder 32e of the water storage tank 32 is accumulated on the lid body 32d. Furthermore, a drainage passage 32f is connected to the wall surface 32g above the lid 32d of the water storage tank 32 so that the cleaning water accumulated on the lid 32d can be discharged to the bowl portion 12.

  The pressurizing pump 34 pressurizes the wash water stored in the water storage tank 32 and discharges it from the jet water outlet 16. The pressurizing pump 34 is connected by a cleaning water pipe 34 a extending from the lower portion of the water storage tank 32, and pressurizes the cleaning water stored in the water storage tank 32. In the present embodiment, the pressurizing pump 34 pressurizes the cleaning water in the water storage tank 32 and discharges the cleaning water from the jet water outlet 16 at a maximum flow rate of about 120 liters / minute. .

  Further, a jet water spouting flapper valve 38 and a water drain plug 39, which are check valves, are provided in the middle of the washing water pipe 34a. The jet water spouting flapper valve 38 and the water drain plug 39 are disposed at a height near the lower end of the water storage tank 32 below the pressurizing pump 34. For this reason, by opening the water drain plug 39, the cleaning water in the water storage tank 32 and the pressure pump 34 can be discharged during maintenance or the like. Further, by disposing a jet water spouting flapper valve 38 between the water storage tank 32 and the pressurizing pump 34, when the water level in the water storage tank 32 becomes lower than the height of the pressurizing pump 34, washing water is added. Backflow from the pressure pump 34 to the water storage tank 32 prevents the wash water in the pressure pump 34 from escaping. A water receiving tray 2a is arranged below the pressurizing pump 34 so as to receive condensed water droplets and water leakage.

  On the other hand, the outlet of the pressurizing pump 34 is connected to the jet water spouting port 16 at the bottom of the bowl portion 12 through a washing water conduit 34b. In the middle of the washing water pipe 34 b, a convex shape is formed upward, and the washing water pipe top 44, which is the highest part of the convex part, is a washing water pipe from the water storage tank 32 to the jet spout 16. It is the highest part of the road. Further, as shown in FIG. 3, the downstream side of the cleaning water pipe top portion 44 of the cleaning water pipe 34 b is set to the same level (height) as the jet water spouting port 16 described above.

  The jet water discharge vacuum breaker 36 is connected to the branch pipe 36a branched from the downstream side of the pressurizing pump 34 and the washing water pipe top 44, and the water stored in the bowl part 12 flows back to the water storage tank 32 side. In addition to preventing this, a edging between them is performed. Further, the washing water overflowing from the air release portion of the jet water spouting vacuum breaker 36 flows into the water storage tank 32 through the return pipe 36b.

  The controller 40 sequentially operates the electromagnetic valve 22, the switching valve 28, and the pressurization pump 34 by the operation of the toilet flushing switch (not shown) by the user, and sequentially discharges water from the rim water outlet 18 and the jet water outlet 16. Start and wash the bowl 12. Further, after the cleaning is completed, the controller 40 opens the electromagnetic valve 22, switches the switching valve 28 to the water storage tank 32 side, and replenishes the water storage tank 32 with cleaning water. When the water level in the water storage tank 32 rises and the upper end float switch 32b detects the specified water storage amount, the controller 40 closes the electromagnetic valve 22 and stops water supply.

In the present embodiment shown in FIG. 3 described above, by switching the switching valve 28, cleaning water is supplied to the rim water spouting port via the rim-side water supply channel 18a, and water is stored via the tank water supply channel 32a. The tank 32 is supplied with cleaning water.
However, in this embodiment, as a modification, instead of the electromagnetic valve 22 and the switching valve 28 shown in FIG. 3 described above, a rim water discharge electromagnetic valve and a tank water supply electromagnetic valve may be provided. Specifically, the electromagnetic valve for rim water discharge is provided on the downstream side of the constant flow valve 20, and is connected to the rim side water supply path 18a. The tank water supply solenoid valve is provided on the downstream side of the constant flow valve 20 and is connected to the tank water supply passage 32a. Furthermore, opening / closing operations (ON and OFF operations) of these rim water discharge solenoid valve and tank water supply solenoid valve are performed by control signals from the controller 40.

Next, the pressurizing pump 34 of this embodiment will be described in detail with reference to FIG. The pressurizing pump 34 includes a pump body 46, and the pump body 46 is directly connected to an electric motor (DC motor) 50 via a rotating shaft 48. The pump main body 46 includes an impeller 46a, and the electric motor 50 includes a rotor 50a. The impeller 46a and the rotor 50a are attached to a rotating shaft 48. The rotating shaft 48, the impeller 46 a, and the rotor 50 a serve as the rotating part 52 of the pressurizing pump 34.
As will be described in detail later, even if a power failure occurs during the operation of the pressurizing pump 34, the rotation of the rotating portion 50 of the pressurizing motor 34 due to the inertial force causes the drain trap pipe 14 and the bowl portion 12 to move. An amount of cleaning water necessary for sealing communication can be supplied.

Next, the operation (operation) of the flush toilet 1 according to the embodiment of the present invention described above will be described. First, the basic operation of the flush toilet 1 will be described with reference to FIG.
As shown in FIG. 5, when a toilet flushing switch (not shown) is operated in the standby state (time t0 to t1), the first rim water discharge (pre-rim washing) is started (time t1). That is, when the user operates a toilet flushing switch (not shown), the controller 40 sends a signal to the electromagnetic valve 22 to open it, and also switches the switching valve 28 to the rim water spouting port 18 side by the water supply pressure. Wash water is discharged from the rim spout 18. When the electromagnetic valve 22 is opened, the wash water supplied from the water supply flows into the constant flow valve 20 from the water inlet 20a through the stop cock 42a, the strainer 42b, and the branch fitting 42c. In the constant flow valve 20, when the water supply pressure is high, the flow rate of the wash water that is passed is limited to a predetermined flow rate, and when the water supply pressure is low, the wash water is passed as it is without restricting the flow. The The washing water that has passed through the constant flow valve 20 passes through the electromagnetic valve 22 and the switching valve 28, passes through the rim water discharge vacuum breaker 24, the rim water discharge flapper valve 26, and the rim-side water supply path 18 a, and reaches the upper part of the bowl portion 12. It is discharged from the rim spout 18 that opens to the rear left side. The washing water discharged from the rim water spouting port 18 flows downward while turning in the bowl portion 12, and the inner wall surface of the bowl portion 12 is washed.

Thereafter (time t2), jet water discharge is started, and at the same time, supply of washing water to the water storage tank 32 is also started.
First, the controller 40 sends a signal to the pressurizing pump 34 to activate it, and keeps the pump speed at N1. When the pressurizing pump 34 is activated, the wash water stored in the water storage tank 32 flows into the pressurizing pump 34 through the jet water spouting flapper valve 38 and the drain plug 39 and is pressurized. The washing water pressurized by the pressurizing pump 34 passes through the washing water pipe top 44 of the washing water pipe 34b and is discharged from the jet water outlet 16 opened at the bottom of the bowl part 12.
At this time, the air staying in the vicinity of the washing water pipe top portion 44 of the washing water pipe 34b reaches the jet water spouting vacuum breaker 36 through the branch pipe 36a, and is discharged from the atmosphere opening portion.

  The washing water discharged from the jet spout 16 flows into the drain trap pipe 14 and fills the drain trap pipe 14 to cause a siphon phenomenon. Due to this siphon phenomenon, the accumulated water and dirt in the bowl portion 12 are sucked into the drain trap pipe 14 and discharged from the drain pipe D. Here, in the present embodiment, since the pressurizing pump 34 first rotates at the pump rotation speed N1 (time t2 to t3), the pressurizing force increases, and the washing water is supplied from 75 liters / minute to 120 liters / minute. Can be discharged from the jet spout 16 at a large flow rate within the range, thereby causing a siphon phenomenon in the drain trap pipe 14 to be rapidly caused and water and filth in the bowl portion 12 to be quickly discharged. .

Thereafter (time t3), the pressure of the pump is slightly reduced by reducing the number of rotations of the pump to N2, and the jet water is continuously discharged at a large flow rate within a range of 60 liters / minute to 70 liters / minute. The water is discharged from the water port 16.
Further, the rotational speed N2 of the pump is such a value that the jet water discharge becomes a flow velocity (about 2.5 meters / second or more) necessary for transporting the filth to the top 14d of the drain trap pipe 14.

  In the present embodiment, since a large amount of jet water spouting is continuously supplied in this way, the amount of air sucked from the inlet portion 14a of the drain trap pipe 14 is reduced, and further, the jet water spouting the drain trap. Colliding with the lower wall surface of the inlet portion 14a of the pipe line 14, a swirling flow is generated at the inlet portion, and the swirling flow seals the inlet portion with water, thereby continuing the siphon action. In this way, while the previously generated siphon action is maintained, a large flow rate of jet water spouting continuously causes an extrusion action, and this extrusion action quickly discharges the floating filth remaining in the bowl. can do.

  In the present embodiment, as indicated by a broken line in FIG. 5, the pump rotational speed may be maintained as N1 without being reduced to N2 (time t3 to t4).

Furthermore, in this embodiment, at the end of the jet water discharge at the pump rotation speed N2 (time t4 to t5), the rotation speed of the pressure pump is controlled so that the water discharged from the jet water discharge port gradually decreases. Yes.
Thereby, generation | occurrence | production of the big siphon interruption sound which arises when a siphon effect | action interrupts suddenly can be prevented.

  Thus, by operating the pressurizing pump 34 for a predetermined time (time t2 to t5), the wash water is discharged from the jet water outlet 16, and the amount of water stored in the water storage tank 32 becomes substantially zero. By stopping the pressurizing pump 34, water discharge from the jet water discharge port 16 is stopped (time t5). As a result, air is introduced from the jet water spouting vacuum breaker 36 into the cleaning water conduit, and the stored water in the bowl portion 12 and the cleaning water in the water storage tank 32 are separated.

  In the present embodiment, cleaning water is supplied to the water storage tank 32 at the same time during jet water discharge (time t2 to t5). At this time, the controller 40 sends a signal to the switching valve 28 while switching the solenoid valve 22 to the tank side while keeping the electromagnetic valve 22 open. Since the electromagnetic valve 22 is opened, the wash water flowing in from the water inlet 20a passes through the constant flow valve 20, the electromagnetic valve 22, the switching valve 28, and the tank water supply path 32a, and stores water from the tip of the tank water supply path 32a. It flows into the tank 32.

  Next, when the jet water discharge is completed (time t5), the controller 40 sends a signal to the electromagnetic valve 22 to open it again, and starts the second water discharge (rear rim cleaning) from the rim water discharge port 18. Let The water level in the bowl portion 12 rises due to the second water discharge from the rim water spouting port 18, and after the predetermined rim water discharge time has elapsed (time t6), the inside of the bowl portion 12 reaches the predetermined water level.

  After completion of the second rim water discharge (time t6), the washing water in the water storage tank 32 is supplied again. At this time, as described above, the controller 40 sends a signal to the switching valve 28 in a state where the electromagnetic valve 22 is kept open, switches it to the tank side, and flows into the water storage tank 32.

When washing water is replenished in the water storage tank 32 and the water level in the water storage tank 32 reaches a specified water storage level, the float switch 32b is turned on. When the float switch 32b is turned on, the controller 40 sends a signal to the electromagnetic valve 22 to close it.
Here, the values of the times t1 to t7 shown in FIG. 5 are t1 = 0 seconds, t1 to t2 = 10 seconds, t2 to t5 = 2 seconds, t5 to t6 = 11 seconds, and t6 to t7 = 16 seconds. preferable.

  Next, with reference to FIG. 6 to FIG. 8, the operation when a power failure occurs during operation of the pressurizing pump by the flush toilet according to the present embodiment will be described. Here, FIG. 6 is a time chart showing the number of rotations of the pump when a power failure occurs during the operation of the pressurizing pump of the flush toilet according to the present embodiment, and FIG. FIG. 8 is a cross-sectional view showing a flush toilet that is at the water level (reserved water amount), and FIG. 8 is the minimum stored water level (minimum stored water amount or minimum sealed water amount) necessary for sealing the drain trap pipe and bowl. FIG. 9 is a series of cross-sectional views of the flush toilet illustrating the operation of the flush toilet according to the present embodiment during a power failure.

First, as shown in FIG. 7, the normal water level (the amount of water) after use of the toilet is at the level A where the water in the bowl 12 is accumulated up to the top 14d of the drain trap line 14. .
In addition, as shown in FIG. 8, the minimum accumulated water level (minimum accumulated water amount or minimum sealed water amount) necessary for sealing the drain trap conduit 14 and the bowl portion 12 is that the accumulated water is the drain trap conduit 14. The level B position is accumulated up to the upper end portion 14e of the inlet portion 14a.

Next, with reference to FIG. 6 and FIG. 9, the operation when a power failure occurs during the operation of the pressurizing pump by the flush toilet according to the present embodiment will be described.
First, FIG. 9A shows a standby state (time t0 to t1 in FIG. 6), in which water is stored in the bowl portion 12. FIG. The water level of the water storage tank 32 at this time is level L1.

  Next, as shown in FIG. 9B, after the rim water spouting, when the jet water spouting is started (time t2 in FIG. 6), the pump rotates at the rotational speed N1, and the drain trap is caused by the jet flow having a large flow rate. The pipeline is full of water. After that (time t3 in FIG. 6), a large flow rate of jet water is continuously supplied, so that the siphon action is continued. The water level of the water storage tank 32 at this time is, for example, level L2.

  Here, when the siphon action is occurring (time t3 to t5 in FIG. 6), that is, when a power failure occurs while the pressure pump 34 is operating (time t8 in FIG. 6), FIG. As shown in c), the function of the electric motor 50 of the pressure pump 34 is immediately stopped. The water level of the water storage tank 32 at this time is level L3. At this time, the jet water spouting vacuum breaker 36 attached to the cleaning water pipe 34b introduces air into the cleaning water pipe 34b, and the siphon action disappears. As a result, the drain trap pipe 14 has a trap rising pipe 14b. The remaining water C (see FIG. 9 (d)) of the cleaning water amount Q1 returns to the bowl portion 12 and acts as part of the sealed water.

  Next, as shown in FIG. 9D, the pump body 34a has a mass of the rotating portion 52 (= rotating shaft 48 + impeller 46a + rotor 50a) of the pressurizing pump 34 even after the function of the motor 34c is stopped due to a power failure. Due to the inertial force, the motor rotates by a preset number of times and stops. Specifically, as shown in FIG. 6, when a power failure occurs at time t8, the pump body 46 rotates as many times as necessary until time t9. The washing water in the water storage tank 32 is supplied to the washing water pipe 34b by the rotation of the rotating part 52 due to the inertial force, and the washing water causes the pressurization pump 34 and the washing water pipe top 44 in the washing water pipe 34b to be supplied. Wash water remaining in between is pushed out to the bowl 12 side. At this time, as shown in FIG. 9 (d), the water level of the water storage tank 32 is lowered to the level L4. As described above, after the power failure, the washing water amount Q2 (the amount of washing water between the level 3 and the level L4 in the pressurized tank) is supplied to the bowl portion 12 by the rotation by the inertial force of the rotating portion 52 of the pressurizing pump 34. It is like that.

  Next, FIG.9 (e) has shown the state which rotation of the pump main body 46 stopped after the power failure. In this state, as described above, the bowl portion 12 is supplied with the cleaning water amount Q1 in the trap rising pipe 14b of the drain trap pipe 14 and the cleaning supplied by the rotation by the inertial force of the rotating portion 52 of the pressurizing pump 34. The total amount of washing water (Q1 + Q2) with the amount of water Q2 is stored as sealed water. The level D of the sealed water at this time is the above-mentioned level B (FIG. 8) which is the minimum water level (minimum water level or minimum water level) necessary for sealing the drain trap pipe 14 and the bowl portion 12. Level) or higher.

  In the flush toilet according to the above-described embodiment, in order to ensure the minimum water level (minimum water level or minimum water level) necessary for sealing the drain trap pipe 14 and the bowl 12, The total amount of washing water (Q1 + Q2) of the amount of washing water Q1 in the trap rising pipe 14b of the drain trap pipe 14 and the amount of washing water Q2 supplied by the rotation of the inertial force of the rotating part 52 of the pressurizing pump 34 is stored as water. Used as (sealed water). However, in the present embodiment, when the amount of washing water Q1 in the trap rising pipe 14b of the drain trap pipe 14 greatly fluctuates due to the structure of the flush toilet, etc., the rotation part 52 of the pressurizing pump 34 The minimum amount of stored water (minimum amount of stored water or minimum amount required for sealing the drain trap pipe 14 and the bowl portion 12 by supplying the necessary amount of cleaning water by the amount of cleaning water Q2 supplied by the rotation of inertial force. You may make it ensure the amount of sealing water. In this case, the mass of the rotating part 52 (= rotating shaft 48 + impeller 46a + rotor 50a) of the pressurizing pump 34 is adjusted so that the necessary amount of cleaning water can be supplied by the inertial force during a power failure. There is a need to.

  As described above, according to the flush toilet according to the present embodiment, when the pressurizing pump 34 is operated and the wash water stored in the water storage tank 32 is pressurized and supplied to the jet spout 16, Even in the event of a power failure, the required amount of cleaning water can be supplied by rotating the required number of times by the inertial force of the rotating part 52 of the pressurizing pump 34. Can be supplied to the jet spout and the communication between the drain trap pipe and the bowl portion can be sealed. As a result, bad smell can be prevented from entering the toilet from the sewer pipe.

  In this embodiment, even if a power failure occurs, the inertial force of the rotating portion 52 of the pressurizing pump 34 is adjusted to return the amount Q1 of the return cleaning water in the drain trap pipe and the pressurizing pump 34. Since the communication with the drain trap pipe 14 and the bowl part 12 is sealed by the sum of the amount Q2 of cleaning water supplied by the rotation of the rotating part 52 due to the inertial force, the drain trap pipe and the bowl are sealed. Communication with the part can be sealed.

  Furthermore, in this embodiment, even if a power failure occurs, the drainage trap pipe is adjusted by adjusting the inertial force of the rotating portion 52 of the pressurizing pump 34 and at least the amount of cleaning water supplied by the rotation due to the inertial force. Since the communication between the path and the bowl portion can be sealed, the communication between the drain trap pipe and the bowl portion can be sealed.

It is a side view of the flush toilet according to one embodiment of the present invention. It is a top view of the flush toilet shown in FIG. 1 is an overall configuration diagram showing a flush toilet according to an embodiment of the present invention. It is a fragmentary sectional view showing the pressurization pump used for the flush toilet according to one embodiment of the present invention. It is a time chart which shows the basic operation | movement in the flush toilet by one Embodiment of this invention. It is a time chart which shows the number of rotations of a pump when a power failure occurs during operation of a pressurizing pump of a flush toilet according to an embodiment of the present invention. It is sectional drawing which shows the flush toilet which is the normal stored water level (the amount of stored water) after using the toilet. It is sectional drawing which shows the flush toilet which is the minimum stored water level (the minimum amount of stored water or the minimum amount of sealed water) required in order to seal a drain trap pipe and a bowl part. It is a series of sectional views of the flush toilet which shows the operation at the time of a power failure of the flush toilet according to one embodiment of the present invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Flush toilet 2 Toilet bowl main body 10 Functional part 12 Bowl part 14 Drain trap pipe 16 Jet water outlet 18 Rim water outlet 18a Rim side water supply path 20 Constant flow valve 22 Solenoid valve 28 Switching valve 32 Water storage tank 34 Pressure pump 34b Cleaning Water pipe line 36 Vacuum breaker for jet water discharge 40 Controller 46 Pump body 46a Impeller 48 Rotating shaft 50 Electric motor 50a Rotor 52 Rotating part

Claims (4)

A flush toilet flushed with pressurized wash water,
A toilet body including a bowl portion, a rim spout and a jet spout for discharging washing water, and a drain trap conduit;
A water storage tank for storing cleaning water;
Washing water supply means for supplying cleaning water to the rim spout and supplying the water storage tank to the jet spout, wherein the cleaning water supply means is driven by electric power supplied from a power source. Cleaning water supply means,
The cleaning water supply means includes a pressurizing pump that pressurizes the cleaning water stored in the water storage tank and supplies the pressurizing water to the jet water spouting port. It is configured to supply the jet water outlet with an amount of cleaning water necessary for sealing the communication between the drain trap pipe and the bowl portion by the rotation by the inertia force of Flush toilet.   The pressurizing pump is configured so that the communication between the drain trap pipe and the bowl portion can be sealed by at least the amount of cleaning water supplied by the rotation due to the inertial force of the rotating portion. The flush toilet according to claim 1, wherein inertia force is set. The pressurizing pump includes the drain trap pipe, the bowl part, and the sum of the quantity of wash water supplied by rotation by the inertial force of the rotary part and the return wash water in the drain trap pipe. The flush toilet according to claim 1, wherein an inertial force of rotation of the rotating portion is set so that communication between the two can be sealed.
The flush toilet shown.   The flush toilet according to any one of claims 1 to 3, wherein an amount of washing water necessary for sealing communication between the drain trap pipe and the bowl portion is in a range of 700cc to 1300cc. .

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