JP2019218769A - Drainage system - Google Patents

Abstract

To provide a drainage system capable of efficiently suppressing adhesion of urinary stones and dirt in a horizontal drawing conduit line and removing urinary stones and dirt adhering to the inside of the horizontal drawing conduit line.SOLUTION: A drainage system 10 has: a horizontal drawing conduit line 11 through which sewage from a urinal 1 flows and discharges sewage to a drainage section 9 provided in the building; a circulation path 13 is formed by the horizontal drawing conduit line 11 and a return path 12 branched out from the downstream area of the horizontal drawing conduit line 11 and connected to the upstream area of the horizontal drawing conduit line 11; and in the circulation path 13, arranged are a circulation pump 16, and an air bubble mixing section 18 for mixing air bubbled into sewage.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a drainage system attached to a urinal.

  Sewage flowing down from a plurality of urinals on an arbitrary floor in a building such as a building is discharged to a vertical drain pipe provided in the building through a horizontal drawing pipe provided below the urinal. . Since the horizontal drawing pipe is a pipe in the horizontal direction, the flow of water is deteriorated, and there is a possibility that the water may stay. Therefore, urine remaining in the pipe may be deposited as urolith.

  In order to remove the urine stones deposited in the pipe in this manner, and to suppress the adhesion of dirt such as urine stone to the pipe, a washing water containing a chemical is flowed into the horizontal drawing pipe, or a large amount of A method of flowing washing water has been proposed. For example, Patent Literature 1 proposes to periodically increase the flow rate of cleaning water.

JP 2013-155523 A

  However, the above-described conventional method requires a chemical and a large amount of washing water, and thus may increase the operating cost.

  The present invention has been proposed in view of such circumstances, and an object thereof is to efficiently suppress the adhesion of urine stones and dirt in the horizontal drawing channel, and to reduce the urine attached to the horizontal drawing channel. It is to provide a drainage system capable of removing stones and dirt.

  In order to achieve the above object, the drainage system of the present invention is a drainage system having a horizontal draw pipe through which sewage flows from a urinal and discharges the sewage to a drainage unit provided in a building. A horizontal drawing pipe, a circulation path is formed by a return flow path branched from a downstream area of the horizontal drawing pipe and connected to an upstream area of the horizontal drawing pipe, and a circulation pump is formed in the circulation path. And an air bubble mixing portion for forming air into the sewage and mixing the air with the waste water.

  Since the drainage system of the present invention has the above-described configuration, it is possible to efficiently suppress the adhesion of urine and dirt in the horizontal drawing pipe, and to remove the urine and dirt attached to the horizontal drawing pipe. You can also.

It is a schematic system diagram of a drainage system concerning one embodiment of the present invention. It is a general | schematic expanded longitudinal cross-sectional view which abbreviate | omitted some and shows an example of washing | cleaning in the horizontal drawing pipeline in the same drainage system. It is a time chart which shows the circulation timing of the same drainage system.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. First, a schematic basic configuration of the drainage system 10 will be described.

  The drainage system 10 has a horizontal draw pipe 11 that receives sewage from the urinal 1 and discharges the sewage to a drainage section (in this embodiment, a vertical drainage pipe 9) provided in the building. It is. In the drainage system 10, a circulation path 13 is formed by a horizontal drawing pipe 11, a return flow path 12 branched from a downstream area of the horizontal drawing pipe 11, and connected to an upstream area of the horizontal drawing pipe 11. ing. The circulation path 13 is provided with a circulation pump 16 and a bubble mixing section 18 for forming air into the sewage and mixing it.

  The drainage system 10 is a system related to a drainage mechanism provided downstream of the plurality of urinals 1 in common with the plurality of urinals 1. In the present embodiment, as described above, the drainage system 10 includes the circulation path 13 disposed on the downstream side of the urinal 1 as a main component, but the drainage system 10 includes the urinal 1 and other components. It may be configured to include a certain water supply path 2, a branch path 3, a discharge path 5, and the like.

  Hereinafter, the urinal 1 and its peripheral mechanism and the drainage system 10 will be described in detail with reference to FIGS. In the present embodiment, an example of an arbitrary floor when the drainage system 10 is provided on each floor of a building such as a building is shown. As shown in FIG. 1, sewage discharged from all urinals 1 is The water is discharged to a drainage section formed by a vertical drainage pipe 9 communicating vertically. In FIG. 1, the flow of water is schematically shown by arrows.

  The urinal 1 is connected to the water supply channel 2 via the individual branch channels 3 so that the flush water is supplied through a common water supply channel 2 to a plurality of toilets. Further, the urinal 1 is connected to the horizontal pulling channel 11 via the individual drain channels 5 so as to discharge sewage (urine and washing water) to the horizontal pulling channel 11 common to a plurality of toilets. The horizontal drawing pipe 11 is inclined downward toward the downstream, and is drained to the vertical drain pipe 9 unless sewage is circulating.

  The urinal 1 includes a bowl portion 1a, a water supply portion 1b connected to the branch passage 3, and a discharge portion 1c connected to the discharge passage 5. The water supply unit 1b includes a discharge unit such as a spreader that discharges washing water sent from the water supply passage 2 through the branch passage 3 along the inner surface of the bowl unit 1a. The discharge unit 1c constitutes a trap unit, and is configured to discharge sewage to the discharge path 5.

  Further, a water supply valve 4 is provided in the branch passage 3, and the water can be supplied to the bowl portion 1a of the urinal 1 by opening the water supply valve 4 by a washing operation or a sensor operation for each urinal 1. It has become.

  The discharge channel 5 provided for each urinal 1 is connected to the horizontal pulling line 11 as described above, and the horizontal pulling line 11 is connected to the drainage portion including the vertical drainage pipe 9 on the downstream side. ing. Therefore, the sewage (urine and washing water) discharged from the urinal 1 is discharged to the vertical drain 9. The drainage section may be a drainage basin.

  The present drainage system 10 is a circulation system including the above-mentioned horizontal drawing pipeline 11. Specifically, as described above, the branching operation is performed in the circulation path 13 that branches from the downstream area of the horizontal drawing pipe 11 to the return flow path 12 and is connected to the upstream area of the horizontal drawing pipe 11. System. Note that the upstream area and the downstream area of the horizontal drawing pipe 11 are in a vertical relationship in the flow of water and are relative. As in the example of FIG. 1, it is desirable that the branch portion 11a is located downstream of the position where the most downstream discharge path 5 is connected, and the return portion 11b is located at the position where the most upstream discharge path 5 is connected. It is desirable to be on the upstream side.

  A pump 16 is disposed in such a circulation path 13, and the pump 16 draws sewage in the horizontal drawing pipe 11 to the return flow path 12 through the branch portion 11 a, and further, draws the wastewater through the return section 11 b. The road is returned to the upstream area. In the illustrated example, the pump 16 is disposed in the return portion 11b, but is not limited to this. Further, a check valve 15 is disposed in the horizontal drawing conduit 11 so as not to flow back.

  The circulation path 13 is further provided with a bubble mixing section 18 (abbreviated as “MB” in the drawing) adjacent to the pump 16. The bubble mixing section 18 may be configured to mix both or one of microscopic bubbles in millimeter order and micrometer order. In addition, the bubble mixing portion 18 has a void ratio (an area ratio of bubbles included in a unit cross-sectional area of the fluid) of the sewage (fine sewage containing fine bubbles) mixed with the fine bubbles, preferably about 5% to 40%. , May be set to be about 10% to 30%.

  The bubble mixing section 18 is preferably of a type that generates fine bubbles using the water pressure of the pump 16. For example, in the flow path of the sewage, a constricted portion and an enlarged portion are continuously provided, and air is sucked and mixed by a negative pressure generated in the constricted portion, and then the mixed bubbles are refined by a shear force generated in the enlarged portion. (See, for example, FIG. 4 of JP-A-2009-155844). In the present embodiment, as the bubble mixing section 18, one that generates bubbles by the above-described Venturi effect is adopted, and the bubble mixing section 18 is disposed immediately downstream of the pump 16 as shown in FIG. 2. .

  The branching portion 11a between the downstream area of the horizontal drawing pipe 11 and the return flow path 12 connects the return flow path 12 to the lower surface of the horizontal drawing pipe 11, so that the connected portion inside the return flow path 12 Connected so that sewage falls down. Therefore, if there is a gap in the return flow path 12 at the portion where the pump 16 is operated and connected, the sewage falls and circulates in the circulation path 13, and the pump 16 is stopped and connected. If sewage accumulates in the return flow path 12 of the portion, it is discharged to the vertical drain pipe 9. As described above, when the pump 16 is operating, the sewage circulates in the circulation path 13, but when the pump 16 is not operating, the sewage does not flow to the lower return flow path 12 but goes to the horizontal direction and the vertical drain pipe 9. Flows to A switch valve may be provided in the branch part 11a so that the circulation in the circulation path 13 and the discharge to the vertical drain pipe 9 can be switched.

  Further, as shown in FIG. 1, it is desirable to provide a filtration device 14 (filter) in the middle of the return channel 12. During the circulation of the sewage, there is a possibility that sewage containing solids such as foreign substances and body hairs removed from the horizontal drawing pipe 11 may flow into the return flow path 12, but these can be removed by the filtration device 14. .

  Further, on the upstream side of the branch portion 11a in the horizontal drawing pipe 11, and downstream of the position where the discharge path 5 on the most downstream side (the right side in FIG. 1) is connected, the presence / absence of wastewater is detected. A flow meter 17 is provided. The flow meter 17 is for detecting a condition for starting circulation, and will be described later in detail with reference to FIG.

  According to such a drainage system 10, by circulating waste water, the inside of the horizontal drawing pipe 11 can be repeatedly washed with the waste water. If the circulation path 13 does not exist and water does not circulate in the horizontal drawing pipe 11, urine adheres to garbage such as body hairs remaining in the horizontal drawing pipe 11 and the inner surface of the pipe and is concentrated, As a result, urolith may adhere to the inner surface of the tube. However, if the horizontal drawing line 11 is incorporated in the circulation line 13 as in the present drainage system 10, the wastewater passes through the horizontal drawing line 11 many times to clean the inside of the pipe or to remove urine. Concentration is hindered, and urinary stones are less likely to occur. Further, even when urine stones are generated, it is possible to prevent the sewage from adhering to the inner surface of the pipe because the sewage does not stay.

  Further, according to the drainage system 10, since the air bubble mixing section 18 is provided in the circulation path 13, various dirt such as urine stones adhered to the horizontal drawing pipe 11 is removed by the sewage mixed with fine bubbles. It is also possible. The fine air bubbles generated in the air bubble mixing section 18 collide with the inner surface of the horizontal drawing pipe 11 and burst, thereby removing dirt attached to the inner surface. Furthermore, the ultrasonic waves generated at the time of the disintegration of the microbubbles can peel off the dirt adhered to the inner surface of the horizontal drawing conduit 11, thereby preventing the urine stone from adhering.

  As described above, according to the drainage system 10, the circulation of the sewage contributes to the removal of the dirt in the horizontal drawing line 11 and the prevention of the generation of the dirt, and the aging of the horizontal drawing line 11 can be delayed. Frequency can be reduced. Of course, according to the drainage system 10, the generation of dirt in the return flow path 12 can be prevented, and even if dirt is generated on the scale, it can be removed.

  In addition, since the sewage is circulated in the horizontal drawing line 11, a water-saving cleaning system can be configured that can efficiently clean the horizontal drawing line 11 without using a large amount of clean washing water. . Note that, in order to prevent air from being caught by the water supply shortage in the bubble mixing section 18, the cleaning water from the water supply path 2 may be directly supplied to the sewage in the circulation path 13.

  Further, as shown in FIG. 2, the sewage drawn from the return flow path 12 by the pump 16 is sent diagonally forward along the inner surface of the pipe to the horizontal drawing pipe 11 together with fine bubbles from the bubble mixing section 18. It is configured as follows. By sending out in this way, the circulating water containing fine bubbles discharged from the pump 16 flows spirally in the horizontal drawing pipe 11. If the pump 16 is adjusted to flow spirally over substantially the entire length of the tube, it is possible to efficiently clean substantially the entire surface of the tube.

  In the drainage system 10 using the circulation path 13 described above, sewage circulates in the pipe by the above-described configuration, and the circulation control is performed by the control unit 20 (see FIG. 1). This will be described with reference to the time chart of FIG.

  First, the control unit 20 determines that the flush water has been supplied to any one of the urinals 1 by an opening operation of the water supply valve 4 (or a flush operation) (A in FIG. 3).

  Thereafter, the sewage flows to the downstream area of the horizontal drawing line 11, and when a predetermined flow rate is detected by the flow meter 17 and it is determined that there is a water amount, the control unit 20 operates the pump 16 at that timing to cause the inside of the circulation path 13. Of the wastewater is started (FIG. 3B). Bubble mixing starts at substantially the same timing as the start of the circulation (B ′ in FIG. 3). After the circulation starts, the amount of drainage to the vertical drain pipe 9 decreases or the drainage stops.

  Thereafter, when the water supply to the urinal 1 is stopped (C in FIG. 3), the control unit 20 stops the pump 16 and stops the circulation after a predetermined time T has elapsed from that point (D in FIG. 3). The air bubble mixing section 18 is configured to stop the circulation by stopping the circulation (D ′ in FIG. 3) because the air bubble mixing section 18 is configured to interlock with the operation of the pump 16. After the circulation is stopped, the sewage flowing in the horizontal drawing pipe 11 flows into the return flow path 12 or flows out to the vertical drain pipe 9, and if most of the sewage is discharged from the horizontal drawing pipe 11, the flow rate is reduced. There is no water amount based on the total 17 (E in FIG. 3).

  In this way, under the control of the control unit 20, the drainage system 10 may be operated every time the urinal 1 is used and supplied with water, and the wastewater may be circulated in the circulation path 13. In addition, if the circulation time is lengthened, the inside of the horizontal drawing pipe 11 can be cleaned for a long time, and the cleaning action can be enhanced. That is, in the example of FIG. 3, the predetermined time T may be increased, and the circulation time may be increased. Note that the present invention is not limited to the configuration in which the circulation is stopped with a time delay as described above, and may be an operation configuration in which the circulation is stopped by stopping the supply of water to the urinal 1 (C in FIG. 3).

  Further, the drainage system 10 may be operated regardless of the timing of water supply to the urinal 1 or the detection value of the flow meter 17. For example, a timer may be provided to perform a circulating operation at a fixed cycle or a predetermined time. The stop timing may be a certain time after the start.

  Further, for example, the cleaning water may be supplied to the horizontal drawing pipe 11 at a constant cycle, and the cleaning water may be circulated through the circulation path 13 for a predetermined time. That is, the circulation (driving of the pump 16) may be started with the amount of water by the flow meter 17 and stopped after a certain time. In this case, the washing water may be supplied to the horizontal drawing pipe 11 via a bypass (not shown).

  In this case, the flushing water dedicated to circulation is required. However, in the case of the urinal 1 that is not frequently used, since it is possible to circulate the water before urine stones and dirt are attached, This is effective for increasing the cleaning effect in the pulling line 11. In this case, the amount of the cleaning water exclusively used for circulation is smaller than the amount of the cleaning water used in the method disclosed in Patent Literature 1, and the adhesion of urolith can be suppressed.

  In the above embodiment, the flow meter 17 is arranged in the circulation path 13, but may be arranged near the connection of the vertical drain pipe 9 downstream of the circulation path 13. Even in such an arrangement, the presence of water by the flow meter 17 can be used as a circulation start condition.

  Further, if the flow meter 17 is disposed in the circulation path 13 as shown in FIG. 1, the amount of water can be monitored during circulation, and the pump 16 can be stopped when the absence of the amount of water is detected. That is, the presence of water by the flow meter 17 can be used not only as a condition for starting circulation but also as an operating condition. In this way, the circulation can be stopped when the sewage in the circulation path 13 flows out of the circulation path 13 for some reason, even though the circulation is being performed (the pump 16 is operating). The pump 16 may be operated in cooperation with the timing of water supply to the urinal 1 without using the flow meter 17.

  Further, the sewage in the circulation path 13 may be purified by the filtering device 14 or another cleaning device. The purified water may be branched off at the downstream portion of the pump 16 and connected to the water supply channel 2 to be reused as flush water for the urinal 1 (see the flow indicated by a broken arrow in FIG. 1). ).

1 Urinal 9 Vertical drain (drainage section)
DESCRIPTION OF SYMBOLS 10 Drainage system 11 Horizontal drawing pipe 12 Return flow path 13 Circulation path 14 Filtration device 16 Pump 17 Flow meter 18 Bubble mixing part

In order to achieve the above object, the drainage system of the present invention is a drainage system having a horizontal draw pipe through which sewage flows from a urinal and discharges the sewage to a drainage unit provided in a building. A horizontal drawing pipe, a circulation path is formed by a return flow path branched from a downstream area of the horizontal drawing pipe and connected to an upstream area of the horizontal drawing pipe, and a circulation pump is formed in the circulation path. characterized by a bubbly portion of mixing with the air is bubbled into dirty water flowing in the circulation path is disposed.

Claims (3)

A drainage system having a horizontal drawing pipe through which sewage from the urinal flows, and discharges the sewage to a drainage unit provided in the building,
A circulation path is formed by the horizontal drawing pipe and a return flow path branched from a downstream area of the horizontal drawing pipe and connected to an upstream area of the horizontal drawing pipe, and a circulation pump is formed in the circulation path. And a bubble mixing section for forming air into the sewage and mixing the air with the wastewater. In claim 1,
A drainage system, wherein a filtration device is provided in the return channel. In claim 1 or 2,
A drainage system, wherein circulating water discharged from the pump spirals in the horizontal drawing conduit.

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