JP2007120259A - Flush toilet bowl - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a flush toilet bowl which contributes to the saving of water consumption for flushing the same. <P>SOLUTION: The flush toilet bowl is formed of the bowl, a flush water feeding means for feeding flush water into the bowl, and a trap portion arranged in the bowl and on the rear wall lower side of the same, for storing retained water in the bowl. The flush toilet bowl is equipped with a filthy matter guiding means for guiding filthy matter 30 in the bowl 1, toward a trap inlet port of the trap portion, prior to flushing of the bowl. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a flush toilet for discharging filth in a bowl portion of a toilet bowl from a trap portion to an external drain pipe.

  Conventionally, wash water is stored in a low tank for toilet flushing, and the stored water is discharged into the toilet bowl. And by this washing water discharge | emission, the waste in a toilet bowl and sewage are discharged | emitted by the siphon phenomenon to the external drain pipe through the trap part with the pressure. For example, when toilet bowl cleaning is performed in a turn trap type toilet, for example, as shown in FIGS. 10A to 10B, the turn trap portion 4 is rotated downward so that the filth 30 and the stored water 3 are drained to the outside. It is common to drain into the pipe 7 at once (for example, refer to Patent Document 1). FIG. 11 is a time chart of a conventional example. In FIG. 11, A indicates a time for rotating the turn trap portion 4 downward, and B indicates a time for rotating the turn trap portion 4 upward.

However, in the conventional example seen in Patent Document 1, the amount of water used for discharging the filth 30 is increased, which is uneconomical.
JP 2005-213765 A

  The present invention was invented in view of the above-described conventional problems, and an object of the present invention is to provide a flush toilet that can save the amount of water used for toilet flushing.

  In order to solve the above-mentioned problems, the present invention provides a toilet 1, washing water supply means for supplying washing water into the toilet 1, a rear wall 5 b lower side of the toilet 1, and water 3 stored in the toilet 1. In the flush toilet 1 provided with the trap part 4 for storing the sewage, the sewage 30 in the toilet 1 is guided in advance toward the trap inlet 21 side in the trap part 4 prior to toilet flushing. It is characterized by being.

  By adopting such a configuration, a wave is generated in the stored water 3 in the bowl portion 5, and the filth 30 can be guided to the trap inlet 21 side in advance using this wave, so the amount of water is small. However, it becomes possible to wash away the filth 30 completely.

  In addition, the filth guide means 6 preferably includes an air discharge hole 40 for generating a water flow toward the trap inlet 21 side in the stored water 3 by jetting air into the toilet 1. Since air pressure is used, it is more effective in reducing the amount of water used.

  Further, the filth guide means 6 is for discharging a part of the stored water 3 in the toilet 1 to the trap outlet 23 side in the trap part 4 to generate a water flow in the stored water 3 toward the trap inlet 21 side. It is preferable to provide a temporary drainage means. In this case, since a part of the stored water 3 is used, it is more effective in reducing the amount of water used.

  In addition, the filth guide means 6 preferably includes a water supply means for generating a water flow toward the trap inlet 21 in the stored water 3 by pumping water from the outside of the toilet 1 into the toilet 1. The water flow pressure of the stored water 3 can be increased, and the filth 30 can be guided more reliably.

  Further, the filth guide means 6 includes a control circuit 6a for starting toilet cleaning at a timing at which a wave toward the trap inlet 21 is regenerated after the water flow toward the trap inlet 21 is stopped. In this case, the toilet bowl can be washed using the wave toward the trap inlet 21 after the water flow is stopped, and the filth 30 is more reliably secured by the synergistic action of the suction force due to the siphon phenomenon and the water pressure due to the wave. It becomes possible to discharge.

  According to the present invention, a wave is generated in the stored water in the bowl portion, and the waste is guided to the trap inlet side in advance by using the wave, so that the amount of water used for toilet flushing can be saved, which is very economical.

  FIG. 1 shows an example of a siphon-type toilet 1B, FIG. 2 shows a schematic diagram when filth guidance is performed using wave motion, and FIG. 2 shows a block diagram constituting the filth guidance means.

  The siphon-type toilet 1B includes a toilet 1 having a bowl portion 5, a low tank 8 for supplying cleaning water into the toilet 1, and a fixed reservoir 3 ( A trap section 4 for storing the (sealed water) and a control circuit 6a for guiding the filth prior to toilet flushing.

  In the example of FIG. 2, the trap portion 4 communicates with the trap inlet 21 that opens at the bottom of the rear wall 5 b of the bowl portion 5, the trap top portion 22 that is bent upward in a substantially U-shape, and an external drain pipe. The trap outlet 23 is continuously formed in a tubular shape. In addition, an air discharge hole 40 is formed on the front wall 5a side facing the rear wall 5b of the bowl portion 5 toward the trap inlet 21 side, while an air pump 32 is installed outside the toilet 1; The discharge side of the air pump 32 is connected to the air discharge hole 40 via the air tube 31 with a check valve 33.

  When the operation signal from the cleaning operation unit 12 is input, the control circuit 6a drives the air pump 32 by the timer 11 for a preset time. As a result, air is ejected from the air tube 31 into the bowl portion 5 in the direction indicated by the arrow F in FIG. 1 (a), and the sewage 30 in the bowl portion 5 is trapped using the wave of the stored water. It is guided to the inlet 21 side.

  That is, as shown in FIG. 2 (a), air blows out toward the trap inlet 21 in the stored water 3 of the bowl portion 5 to the rear wall 5b side of the bowl portion 5 in the direction indicated by the arrow F1. Wave (hereinafter referred to as “reverse wave”) is generated, and the filth 30 is guided to the trap inlet side, and the accumulated water in the bowl portion 5 at this time is full. Since the large induction force by the stored water acts on the filth 30, the filth 30 is guided smoothly. Further, a part of the accumulated water 3 rises on the trap top portion 22 by this backward wave and is discharged to the trap outlet 23 as indicated by an arrow F2, and the amount of accumulated water in the bowl portion 5 decreases. This drainage is different from normal overflow drainage or siphon drainage. That is, the overflow drainage overflows and drains from the trap top portion 22 due to the increase of the reservoir water in the bowl portion 5, so that the amount of the reservoir water does not change, while the siphon type drains the trap portion 4. The filth 30 and most of the accumulated water are discharged using the pulling force in the flow direction that is generated when the road is full. On the other hand, in the present invention, the filth 30 is guided. A part of the accumulated water 3 is involved in the backward wave and rises to the trap top 22 and is drained. Even after draining, the amount of accumulated water is reduced, but a certain amount of accumulated water is secured. Therefore, it is different from normal overflow drainage and siphon drainage.

  Thereafter, when the air pump 32 is stopped, the backward wave changes to a wave (hereinafter referred to as “forward wave”) directed toward the front wall 5a of the bowl portion 5 as shown in FIG. Due to this forward wave, an inductive force acts on the filth 30 in a direction away from the trap inlet 21. At this time, the amount of accumulated water in the bowl portion 5 is reduced, so that the filth 30 is moved away from the trap inlet 21. The guiding force is weak and the filth 30 can be stopped near the trap inlet 21.

  Thereafter, the electromagnetic valve 15 of the low tank 8 is opened, and the flushing water in the low tank 8 flows into the bowl portion 5 in the direction indicated by the arrow G in FIG. It is preferable to perform the toilet cleaning in accordance with the timing at which the forward wave changes to the backward wave again. In other words, the forward wave hits the front wall 5a of the bowl part 5 and changes again to the backward wave. By flowing the washing water into the bowl part 5 at the timing when the backward wave is generated, the suction force due to the siphon phenomenon and the backward wave are generated. Due to the synergistic action with the water pressure due to the wave, the force to push the filth 30 that has been guided to the trap inlet side in advance toward the trap top 22 is increased, and the filth 30 is in the direction indicated by the arrow F3 in FIG. It is sucked into and discharged.

  Thus, by using the air pressure from the air pump 32, a wave is generated in the stored water 3 in the bowl portion 5, and the method of inducing the filth 30 to the trap inlet 21 side in advance by this wave is small. Even though the amount of water is small, the filth 30 can be completely washed away. Furthermore, by using air for filth induction, the amount of water used for toilet cleaning can be saved, which is extremely economical.

  Further, in this example, when the waste is guided, a part of the stored water 3 is discharged and the amount of the stored water in the bowl portion 5 is reduced, so that the instantaneous discharge amount at the time of toilet cleaning can be reduced. Thereby, for example, in the case of a multi-story building such as a building or a condominium, each trap section 4 of the plurality of toilets 1 is connected to a common external drain pipe 7 (drainage horizontal pipe or drainage standpipe). Even when a plurality of toilet flushing operations are performed at the same time, the instantaneous discharge amount at the time of toilet flushing can be reduced for each toilet 1 so that the generation of negative pressure in the external drain pipe 7 can be suppressed. It is possible to prevent the occurrence of adverse effects due to pressure fluctuations, for example, the fact that other drain traps (for example, washing pan traps) connected to the common external drain pipe 7 are closed or the drainage of the drainage flows backward. There are also advantages.

  In the above embodiment, the filth induction is performed by using the wave generated by the air pressure. However, the filth can be induced by generating the wave by the water pressure.

  In the example of FIG. 4, a water discharge hole 45 is formed on the side of the front wall 5 a facing the rear wall 5 b of the bowl portion 5 toward the trap inlet 21, while the main drain usually provided on the bottom surface of the low tank 8. A sub discharge port is opened separately from the outlet, and the water discharge hole 45 and the sub discharge port are disposed through the bypass pipe 13 disposed inside the toilet 1 (the space portion between the bowl portion 5 and the toilet 1 outer wall). It is connected. The sub discharge port is opened and closed by a sub electromagnetic valve 14 (FIG. 5). First, when an operation signal from the cleaning operation unit 12 is input to the control circuit 6 a, the control circuit 6 a temporarily opens only the sub electromagnetic valve 14 of the low tank 8 for a preset time by the timer 11. As a result, the wash water in the low tank 8 flows into the bowl portion 5 through the bypass pipe 13 in the direction indicated by the arrow F in FIG. 4A to become jet water, and as shown in FIG. 4B. The sewage 30 can be guided to the trap inlet 21 side by utilizing the wave generated in the stored water 3, and the low tank 8 constitutes a water supply means for generating a water flow that becomes a wave. The guidance of the filth 30 by the wave at this time is performed on the same principle as the backward wave described with reference to FIG. Further, when the sub electromagnetic valve 14 of the low tank 8 is closed after a certain period of time and the jet water is stopped, the forward wave described with reference to FIG. 2B is generated, and the main electromagnetic valve 15 (see FIG. 5) is opened, and the cleaning water in the low tank 8 is supplied into the bowl portion 5 in the direction indicated by the arrow G in FIG. The water 3 is sucked and discharged in the direction indicated by the arrow F3 in FIG.

  Thus, by using a part of the washing water in the low tank 8 to guide the filth 30 to the trap inlet 21 side in advance, the filth 30 discharging operation by the toilet cleaning can be performed reliably and smoothly. become. Therefore, the total amount of water used for toilet cleaning can be saved, which is extremely economical.

  Moreover, although the siphon type toilet 1B was illustrated in the said embodiment, filth guidance operation | movement can be performed also in 1 A of turn trap type toilets. 6 shows an example of the turn trap type toilet 1A, FIG. 7 shows a block diagram of the filth guiding means 6, and FIG. 8 shows a time chart. In this example, prior to cleaning the toilet bowl, there is provided a dirt guide means for guiding the dirt 30 in the toilet bowl in advance toward the trap entrance side.

  In the example shown in FIG. 7, the filth guiding means 6 includes a movable trap section 4 (hereinafter referred to as “turn trap section 4”), a motor 9 that rotates the turn trap section 4 up and down, and a turn trap section 4. A detection sensor 10 that detects the uppermost position and the lowermost position, respectively, and a control circuit 6a that includes a timer 11 that controls the time of the motor 9 according to a detection signal from the detection sensor 10 are provided. When an operation signal from the cleaning operation unit 12 is input to the control circuit 6a, the control circuit 6a temporarily rotates the turn trap unit 4 slightly downward M1 for a preset time by the timer 11. As a result, as shown in FIG. 6B, a water flow toward the trap inlet side is generated in the stored water 3 in the bowl portion 5, and the filth 30 is guided to the trap inlet 21 by this water flow (FIG. 6B). State). At this time, since the accumulated water in the bowl portion 5 is full, the guidance force acting on the filth 30 in the direction toward the trap inlet 21 is large, so that the filth 30 can be smoothly guided to the trap inlet 21 side. . The turn trap section 4 constitutes a temporary drainage means for generating a water flow that becomes a wave. Thereafter, the drain trapping is temporarily stopped by keeping the turn trap portion 4 upward. At this stage, the volume of the stored water 3 in the toilet bowl 1 is reduced by the volume indicated by E. Further, after a certain period of time, the turn trap portion 4 is rotated downward M again, and as shown in FIG. 1C, the filth 30 is discharged together with the remaining water 3 and the toilet bowl is washed. At this time, since the filth 30 is guided to the trap inlet 21 side in advance, the filth 30 can be reliably discharged even with a small amount of water. FIG. 8 shows a time chart in the case where the filth is guided by controlling the rotation time of the turn trap part 4, A1 and A2 in the figure are times for rotating the turn trap part 4 downward, and B is a turn A time C for rotating the trap portion 4 upward, C indicates a time for temporarily stopping drainage. In addition, the amount of drainage at the time of filth guidance can be easily adjusted by adjusting the downward time (time C shown in FIG. 8) of the turn trap portion 4.

  Thus, by guiding the filth 30 to the trap inlet 21 side in advance, the filth 30 can be completely washed away even with a small amount of stored water when cleaning the toilet bowl, and the amount of water is sufficient to induce the filth 30 when the filth is induced. Therefore, as in the above embodiment, the total amount of water used for toilet cleaning can be saved, which is economical.

  FIG. 8 illustrates an example of a time control method for performing the filth guiding operation by controlling the rotation time of the turn trap unit 4. However, as another embodiment, the turn trap unit 4 is directed upward and downward. It is also possible to adopt a position detection control method in which a temporary drainage operation is performed by detecting a lateral position between the two. An example is shown in the time chart of FIG. When an operation signal from the cleaning operation unit 12 is input to the control circuit 6a, the control circuit 6a rotates the turn trap unit 4 from the upward direction to the downward M1. A detection signal is sent from the detection sensor to the control circuit 6a, and the control circuit 6a temporarily stops the rotation of the motor 9 for a time D in FIG. Thereby, since the turn trap part 4 is temporarily fixed in the horizontal posture, only a part of the stored water 3 is discharged by overflow and the filth 30 is guided to the trap inlet 21 side. After that, by rotating the motor 9 again and rotating the turn trap portion 4 from the lateral direction to the downward direction M, the remaining water 3 can be discharged and the filth 30 can be completely washed away. In addition, in this example, the turn trap unit 4 is rotated from the top to the side to guide the filth, and further rotated from the side to the bottom to clean the toilet. As shown in FIG. 8, the turn trap unit 4 is There is an advantage that the circuit structure of the control circuit 6a can be simplified because the complicated operation of turning to the side, returning to the top and then rotating again is unnecessary.

It is side surface sectional drawing explaining the filth guidance in the siphon type toilet bowl used for one embodiment of the present invention, (a) shows the state before toilet bowl washing, (b) shows the state after filth guidance, (c) Indicates the state during washing. (A) is a schematic diagram in the case of performing filth guidance by the same wave as above, (b) is a schematic diagram of the state after filth guidance. It is a block diagram which comprises the filth guidance means same as the above. Other embodiments are shown, (a) shows a state before toilet bowl cleaning, (b) shows a state after filth guidance, and (c) is a side cross-sectional view showing a state during toilet bowl cleaning. It is a block diagram relevant to the filth guidance means of FIG. Other embodiments are shown, (a) shows a state before toilet bowl cleaning, (b) shows a state after filth guidance, and (c) is a side cross-sectional view showing a state during toilet bowl cleaning. It is a block diagram relevant to the filth guidance means of FIG. It is a time chart at the time of performing filth guidance same as the above by the rotation time control system of a motor. It is a time chart at the time of performing filth guidance same as the above by the position control system of a turn trap part. (A) (b) is explanatory drawing of the draining operation | movement in the conventional turn trap type toilet bowl. It is a time chart which shows the conventional draining operation | movement.

Explanation of symbols

1 toilet 30 filth 31 air tube 32 air pump 40 air discharge hole

Claims (5)

  In a flush toilet comprising a toilet, a flush water supply means for supplying flush water into the toilet bowl, and a trap portion provided on the lower side of the rear wall of the toilet bowl and for accumulating water in the toilet bowl, A flush toilet comprising a filth guiding means for previously guiding filth in the toilet toward the trap entrance side in the trap portion.   2. The flush toilet according to claim 1, wherein the filth guide means includes an air discharge hole for causing water to flow toward the trap inlet by causing air to be ejected into the toilet.   The filth guidance means includes a temporary drainage means for causing a part of the stored water in the toilet bowl to be discharged to the trap outlet side in the trap part, thereby causing the stored water to flow toward the trap inlet side. The flush toilet according to claim 1, wherein   2. The flush toilet according to claim 1, wherein the filth guide means includes water supply means for generating a water flow toward the trap inlet side in the stored water by pumping water from the outside of the toilet into the toilet.   The filth guide means includes a control circuit for starting toilet cleaning at a timing at which a wave toward the trap inlet is regenerated after the water flow toward the trap inlet is stopped. Item 5. A flush toilet according to any one of Items 1 to 4.

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