JP2022090942A - Siphon drainage system - Google Patents

Abstract

To provide a siphon drainage system capable of suppressing generation of abnormal noise while maintaining drainage capacity brought about by siphon force.SOLUTION: A siphon drainage system includes: a storage tank 20 for storing drainage flowing in from an inflow port 18A; a horizontal pipe 26A connected to the storage tank 20 for discharging the drainage from the storage tank 20 horizontally; a vertical pipe disposed on a downstream side of the horizontal pipe 26A, for generating siphon force by letting the drainage from the horizontal pipe 26A flow down; and an air-supply pipe 30 having an opening 36A on an end side connected to the horizontal pipe 26A and an opening 32A on the other end side disposed at a position in the storage tank 20 vertically above a connecting opening of the horizontal pipe that opens toward the storage tank 20, the air-supply pipe being capable of letting the air inside the storage tank 20 flow into the horizontal pipe 26A.SELECTED DRAWING: Figure 2

Description

The present invention relates to a siphon drainage system provided with a storage tank that temporarily stores and discharges wastewater.

For example, as shown in Patent Document 1, in a drainage system using the siphon force of a siphon drainage pipe, a storage tank is provided between the water supply device and the horizontal pulling pipe of the siphon drainage pipe, and drainage from the water supply device is siphoned. It is known that the water is temporarily stored in the storage tank until the start of the operation. In the drainage system shown in Patent Document 1, for example, when drainage is performed from the bathtub, the drainage discharged from the bathtub flows into the storage tank. The drainage that has flowed into the storage tank flows through the horizontal pulling pipe of the siphon drainage pipe, and then flows into the vertical pipe.

In the siphon drainage pipe, the siphon force is not generated unless the vertical pipe is filled with drainage and falls in the vertical pipe. Therefore, until the siphon force is generated, the amount of drainage from the siphon drainage pipe flows into the storage tank. Since it is smaller than the amount of drainage from the storage tank, the water level of the drainage from the storage tank rises. After that, when the vertical pipe becomes full with drainage and siphon force is generated, the amount of drainage by the siphon drainage pipe exceeds the amount of drainage of the drainage flowing into the storage tank, and the water level of the drainage drops.

Japanese Unexamined Patent Publication No. 2017-190626

By the way, the siphon drainage pipe in which the siphon force is generated sucks the drainage in the storage tank. Therefore, when the water level in the storage tank drops to some extent, the water level in the vicinity of the siphon drainage pipe may drop to the vicinity of the siphon drainage pipe, and the siphon drainage pipe may suck the air inside the storage tank.

When the siphon drainage pipe sucks in the air inside the storage tank together with the drainage, an abnormal noise is generated, and this abnormal noise echoes in the air layer of the storage tank. When an abnormal noise is heard in the air layer of the storage tank, the wall surface of the storage tank may be vibrated, and finally the abnormal noise may be emitted to the outside of the storage tank. Therefore, in Patent Document 1, in order to suppress the above-mentioned abnormal noise, a ventilation unit is provided to allow air outside the storage tank to flow into the inside of the siphon drainage pipe, and air is sucked in on the downstream side of the storage tank. The suction force acting on the drainage in the storage tank is moderately reduced. As a result, air is suppressed from being sucked from the opening portion of the siphon drain pipe in the storage tank, and the generation of abnormal noise is suppressed inside the storage tank.

However, in Patent Document 1, since the air outside the storage tank is constantly flowed into the inside of the siphon drainage pipe to weaken the siphon force, there is a concern that the drainage capacity may be deteriorated.

In view of the above facts, an object of the present invention is to suppress the generation of abnormal noise in the storage tank while maintaining the drainage capacity by the siphon force.

The siphon drainage system according to claim 1 includes a storage tank for storing drainage flowing in from an inflow port, a horizontal pulling pipe connected to the storage tank and laterally discharging the drainage from the storage tank, and the above-mentioned. A vertical pipe that is arranged on the downstream side of the horizontal pull pipe and generates siphon force by flowing down the drainage from the horizontal pull pipe, and an opening on one end side are connected to the horizontal pull pipe and are connected to the other end side. An air supply pipe having an opening arranged above the connection opening of the horizontal pulling pipe to the storage tank in the vertical direction in the storage tank and allowing air in the storage tank to flow into the inside of the horizontal pulling pipe. I have.

In the siphon drainage system according to claim 1, when drainage flows into the storage tank, the drainage is temporarily stored in the storage tank. The drainage that has flowed into the storage tank flows into the vertical pipe through the horizontal pulling pipe, and when the full drainage falls in the vertical pipe due to gravity, a siphon force is generated. When the siphon force is generated, the drainage in the storage tank is sucked toward the vertical pipe, and the drainage becomes a full flow and flows down, so that the drainage can be performed quickly and efficiently.

By the way, at the stage when the drainage flows into the storage tank, the siphon force is not generated in the initial state where the vertical pipe is not yet full, so the siphon drainage is compared with the amount of drainage per unit time flowing into the storage tank. The amount of drainage per unit time by the pipe is small, and the water level of the drainage rises in the storage tank.

Then, when the inside of the vertical pipe becomes full and a siphon force is generated, the inside of the horizontal pulling pipe becomes a negative pressure, the drainage of the storage tank is sucked, and the drainage from the opening of the horizontal pulling pipe provided in the storage tank is drained to the horizontal pulling pipe. Along with the inflow of water, drainage also flows from the air supply pipe to the horizontal pulling pipe, and drainage can be efficiently performed by using the siphon force. When the water level in the storage tank is sufficiently high, air is not sucked in from the opening of the horizontal pulling pipe, so that no abnormal noise is generated due to this.

When the water level of the storage tank drops to near the opening on the other end side of the air supply pipe due to drainage by siphon force, air enters from the opening on the other end side before the air flows into the connection opening of the horizontal pull pipe, and the air is supplied. Air flows into the lateral pulling tube through the trachea. As a result, the drainage by the siphon force is continued, but the suction force is reduced. By reducing the suction force, the suction of air from the opening portion of the horizontal pulling pipe can be suppressed, and the generation of abnormal noise inside the storage tank can be suppressed.

The "horizontal direction" of the "horizontal pulling pipe that discharges drainage in the horizontal direction" is not limited to the horizontal direction, but also includes a slight inclination (for example, 5 degrees or less).

The siphon drainage system according to claim 2 is the siphon drainage system according to claim 1, wherein the air supply pipe extends so that the opening on the other end side becomes the lowermost part in the vertical direction. , Have.

In the siphon drainage system according to claim 2, the drainage to the upstream part of the supply air is sent upward, and the inflow of the drainage to the upstream part of the supply air is limited to the time when the suction force by the siphon is generated. Therefore, it is possible to suppress the accumulation of dirt and foreign matter on the air supply pipe.

In the siphon drainage system according to claim 3, an intake hole is formed on the side surface of a pipe vertically lower than the upper end of the inflow port in the upstream portion of the air supply.

In the siphon drainage system according to claim 3, when the water level of the storage tank drops to the vicinity of the intake hole of the air supply pipe due to the drainage by the siphon force, the intake air is taken before the air flows into the opening on the other end side of the air supply pipe. Air enters through the hole and flows into the horizontal pulling pipe through the air supply pipe. By adjusting the amount of air flowing in from the intake hole, the suction force of the siphon can be reduced in two steps. As a result, it is possible to suppress the suction of air from the opening portion of the horizontal pulling pipe and suppress the generation of abnormal noise inside the storage tank while ensuring the continuation of drainage by the siphon force.

In the siphon drainage system according to claim 4, an inspection port is formed in the upper part of the storage tank, and at least a part of the upstream portion of the air supply is arranged at a position where the inspection port and the inspection port are horizontally overlapped with each other.

According to the siphon drainage system according to claim 4, maintenance and inspection of the upstream part of the air supply can be easily carried out from the inspection port.

According to the siphon drainage system of the present invention, there is an excellent effect that the generation of abnormal noise in the storage tank can be suppressed while maintaining the drainage capacity by the siphon force.

It is a side view which shows the whole structure of the siphon drainage system which concerns on this embodiment. It is sectional drawing which shows the storage tank of the siphon drainage system which concerns on this embodiment, and the inside thereof. It is a neighborhood view of the hole of the air supply upstream part of the siphon drainage system which concerns on this embodiment. (A) for explaining the drainage of the siphon drainage system according to the present embodiment, (B) showing a state where the water level is higher than (A), and (C) showing a state where the water level is higher than (B). It is a figure. A state in which the water level is lower than in FIG. 4 (C) for explaining the drainage of the siphon drainage system according to the present embodiment (D), a state in which the water level is higher than in (D) (E), and (E) are shown. It is a figure (F) which shows the state which the water level rises more than). It is sectional drawing which shows the storage tank of the siphon drainage system which concerns on the modification of this embodiment, and the inside thereof.

The siphon drainage system 10 according to the embodiment of the present invention will be described with reference to the drawings. The siphon drainage system 10 according to the present embodiment is a drainage system that efficiently discharges drainage from a water supply device by utilizing siphon force.

As shown in FIG. 1, a floor panel 16 is arranged on the upper side of the slab 14 of the building 12 at a distance from the slab 14. A water supply device 17 is arranged on the floor panel 16. The water supply device 17 is for draining drainage from a bathtub, a kitchen sink, a dishwasher, etc., but may be a washbasin, a bathroom waterproof pan, or the like.

One end of a pipe 18 for flowing drainage discharged from the water supply device 17 is connected to the water supply device 17. The pipe 18 is, for example, a pipe made of vinyl chloride, but may be made of another synthetic resin.

(Reservoir)
As shown in FIG. 2, a storage tank 20 constituting a part of the siphon drainage system 10 is arranged on the slab 14.
The storage tank 20 can temporarily store the drainage from the water supply device 17, and is formed in a box shape. The storage tank 20 is a substantially rectangular parallelepiped, and the top plate 20A and the bottom plate 20B are inclined so as to be lowered toward the L direction side of the drawing. The storage tank 20 is made of a synthetic resin material such as vinyl chloride.

An inflow port 18A is formed on one side wall 20C on the side of the storage tank 20 in the direction of arrow R in the drawing, and the other end of the pipe 18 is connected to the inlet 18A. The drainage from the water supply device 17 is configured to flow into the inside of the storage tank 20 through the pipe 18. An outlet 22A as a connection opening is formed on the lower side of the other side wall 20D on the side in the direction of arrow L in the drawing facing the one side wall 20C of the storage tank 20. One end of the pipe 22 is connected to the outlet 22A. The inflow port 18A is arranged on the upper side in the vertical direction with respect to the outflow port 22A.

An inspection port 20E is formed on the top plate 20A of the storage tank 20. The inspection port 20E is closed by a lid 21 that can be opened and closed. Further, one end of the ventilation pipe 23 is connected to the top plate 20A. The other end of the ventilation pipe 23 is connected to the vertical pipe 28 (see FIG. 1) via a merging joint 29 (see FIG. 1) described later.
The pipe 22 and the ventilation pipe 23 are, for example, pipes made of vinyl chloride, but may be made of other synthetic resin.

The pipe 22 is inclined so as to be lowered toward the L direction of the arrow. A T-shaped joint 24 is arranged on the other end side of the pipe 22. The T-shaped joint 24 has a first connection portion 24A to which the pipe 22 is connected, a second connection portion 24B arranged on the opposite side of the first connection portion 24A, and a first connection portion 24A and a second connection portion 24B. A third connecting portion 24C, which is arranged between them and extends upward at right angles to the direction connecting the first connecting portion 24A and the second connecting portion 24B, is provided. The first connection portion 24A and the second connection portion 24B are provided coaxially, and the center line CL of the first connection portion 24A and the second connection portion 24B is inclined so as to be lowered toward the arrow L direction side. ing.

The distance DL from the intersection P of the center line CL1 of the first connection portion 24A of the T-shaped joint 24 and the center line CL2 of the second connection portion 24B to the inner surface of the storage tank 20 is the intersection P and the storage tank 20 at the time of drainage. The drainage route between the two may be set so that the drainage is full, and the pipe 22 may be abolished and the T-shaped joint 24 may be directly connected to the storage tank 20 so that the distance DL is shortened. The pipe 22 may be longer than in FIG. 2 so that the distance DL becomes longer.
The T-shaped joint 24 is made of, for example, vinyl chloride, but may be made of another synthetic resin.

(Siphon drainage pipe)
A siphon drainage pipe 26 that constitutes a part of the siphon drainage system 10 is connected to the second connection portion 24B of the T-shaped joint 24. The siphon drainage pipe 26 includes a horizontal pulling pipe 26A and a vertical pipe 26B. The upstream end of the horizontal pulling pipe 26A is connected to the second connecting portion 24B. A part of the horizontal pull pipe 26A in the vicinity of the T-shaped joint 24 is inclined, but the downstream side thereof is arranged on the slab 14 with no slope in the lateral direction. As shown in FIG. 1, the vertical pipe 26B continuously extends downward (vertically downward) from the downstream end of the horizontal pulling pipe 26A, and the downstream end is connected to a merging joint 29 described later.

The siphon drain pipe 26 of the present embodiment is made of polybutene, but may be made of another flexible synthetic resin.

In the present embodiment, the horizontal pulling pipe 26A, the section between the first connecting portion 24A and the second connecting portion 24B of the T-shaped joint 24, and the pipe 22 correspond to the horizontal pulling pipe of the present invention.

The building 12 is provided with a vertical pipe 28 extending in the vertical direction. A merging joint 29 is attached to the vertical pipe 28, and the drainage flowing through the siphon drainage pipe 26 is discharged to the vertical pipe 28 via the merging joint 29.

An air supply pipe 30 is connected to the third connection portion 24C of the T-shaped joint 24. The air supply pipe 30 is composed of a pipe having a diameter similar to that of the siphon drain pipe 26 or smaller than that of the siphon drain pipe 26, and has an air supply upstream portion 32, an air supply middle flow portion 34, and an air supply downstream portion 36. ing. The air supply downstream portion 36 has an opening 36A on one end side (one end side of the air supply pipe 30) connected to the third connection portion 24C and extends upward. The air supply middle flow portion 34 extends from the upstream end of the air supply downstream portion 36 toward the storage tank 20, penetrates the side wall 20D, and extends into the storage tank 20.

The air supply upstream portion 32 is inclined so as to approach the bottom plate 20B from the tip of the air supply midstream portion 34 arranged in the storage tank 20 toward the arrow R direction. The opening 32A at the tip of the air supply upstream portion 32 (the other end side of the air supply pipe 30) is arranged vertically above the upper end E2 of the outlet 22A. Further, the opening 32A is arranged at a position where it overlaps with the inspection port 20E in the top view.

An intake hole 32B is formed on the side wall of the air supply upstream portion 32. As shown in FIG. 2, the intake hole 32B is formed below the upper end E1 of the inflow port 18A and above the opening 32A. Further, the intake hole 32B is formed at a position visible from the upper surface side of the side wall of the air supply upstream portion 32 arranged in an inclined manner, in other words, from the upper surface. Further, a plurality of intake holes 32B (two in this embodiment) are formed at the same height in the vertical direction. The opening cross-sectional area of the intake hole 32B is set smaller than that of the opening 32A.

(Action, effect)
Next, the operation and effect of the siphon drainage system 10 of the present embodiment will be described.
The drainage from the water supply device 17 flows into the storage tank 20 through the pipe 18 (see FIG. 4A).

Since the bottom plate 20B of the storage tank 20 is inclined so that the siphon drainage pipe 26 side is lower than the pipe 18 side into which the drainage flows, the drainage can be drained from the pipe 18 side into the storage tank 20. It flows to the side (outlet 22A side) and starts to collect from the siphon drainage pipe 26 side, and the water depth on the siphon drainage pipe 26 side becomes deeper than that on the pipe 18 side (see FIG. 4B).

Then, as the drainage flows into the storage tank 20 and the water level of the drainage in the storage tank 20 rises, the air in the storage tank 20 is pushed and the ventilation pipe 23 connected to the top plate 20A of the storage tank 20. And is discharged to the vertical pipe 28 via the merging joint 29. As a result, drainage can be quickly and efficiently flowed into the storage tank 20.

At the stage when the drainage flows into the storage tank 20, in the initial state where the vertical pipe 26B of the siphon drainage pipe 26 is not fully flowed, the siphon force is not generated, so that the unit time of drainage into the storage tank 20 is per unit time. The amount of drainage per unit time by the siphon drainage pipe 26 is smaller than the amount of drainage, and the water level of the drainage rises in the storage tank 20.

When the inside of the vertical pipe 26B of the siphon drainage pipe 26 becomes full and the drainage falls in the vertical pipe 26B by gravity, a siphon force is generated by the potential energy of the siphon head Hs. When the siphon force is generated, the drainage of the storage tank 20 is sucked from the outlet 22A, and the drainage speed is increased. Further, when the water level of the drainage of the storage tank 20 is higher than that of the intake hole 32B when the siphon force is generated, the drainage in the storage tank 20 is also sucked from the intake hole 32B and the opening 32A and passes through the air supply pipe 30. Is sent to the siphon drainage pipe 26 (see FIG. 4 (C)).

If the water level is higher than the upper end E1 of the inflow port 18A, drainage collects in the pipe 18 and there is a concern that it may affect the water supply device 17, so that a siphon force is generated before the water level reaches the upper end E1 of the inflow port 18A. It is set so that drainage from the storage tank 20 is promoted.

As shown in FIG. 4C, when the water level of the drainage in the storage tank 20 is higher than that of the intake hole 32B, the intake hole 32B and the opening 32A are arranged below the water surface, so that the air supply pipe 30 is reached. No inhalation of air occurs. Therefore, drainage can be promoted without reducing the siphon force.

As shown in FIG. 5D, when the water level of the drainage in the storage tank 20 becomes lower than that of the intake hole 32B, air A is taken into the siphon drainage pipe 26 from the intake hole 32B via the air supply pipe 30. .. As a result, the siphon force is appropriately reduced, and the suction force acting on the drainage in the storage tank 20 is moderately reduced. At this time, since the siphon force continues to act on the drainage, the discharge rate of the drainage in the storage tank 20 is faster than in the case where the siphon force does not act.

As shown in FIG. 5 (E), when the water level of the drainage in the storage tank 20 is further lowered and becomes close to the opening 32A, the water surface in the vicinity of the opening 32A is partially due to the suction force from the air supply pipe 30. As it goes down, air A is sucked into the air supply pipe 30 from the opening 32A. At this time, due to the inflow of air A from the intake hole 32B described above, the siphon force is appropriately reduced and the suction force is weakened, so that the generation of abnormal noise due to the suction of air can be suppressed.

Then, the water level of the drainage in the storage tank 20 further drops, the drainage inflow to the air supply pipe 30 disappears, only the air A flows into the air supply pipe 30, and the inflow amount of the air A into the siphon drainage pipe 26 increases. The siphon power is further reduced. As a result, the suction force acting on the drainage in the storage tank 20 is further reduced. Therefore, even if the water level in the storage tank 20 drops to near the outlet 22A of the pipe 22 (see FIG. 5 (F)), the water level in the vicinity of the outlet 22A is partially lowered to allow the air in the storage tank 20 to flow. Inhalation is suppressed, and the generation of abnormal noise can be suppressed.

In the siphon drainage system 10 of the present embodiment, drainage continues with normal siphon force until the water level in the storage tank 20 drops to the intake hole 32B vertically lower than the upper end E1 of the inflow port 18A. Therefore, when the water level in the storage tank 20 is such that the pipe 18 connected to the upstream side of the inflow port 18A is blocked, drainage is performed without reducing the siphon force, and drainage can be promoted. ..

Further, when the water level in the storage tank 20 drops to the intake hole 32B, the air A flows in from the intake hole 32B to continue the drainage by the siphon force and reduce the suction force, and further, from the outlet 22A. Before sucking in the air A, the air A is made to flow in through the opening 32A. As a result, the siphon force can be reduced in two stages, and while suppressing the generation of abnormal noise due to the suction of air A from the outlet 22A, the drainage capacity according to the water surface height (water storage amount) is secured. Can be done.

Further, in the siphon drainage system 10 of the present embodiment, even if the water level in the storage tank 20 drops to the vicinity of the outlet 22A while the siphon force is generated, the air A is supplied to the horizontal pull pipe 26A from the opening 32A. Therefore, by reducing the suction force, the suction of air from the opening portion of the horizontal pulling pipe can be suppressed, and the generation of abnormal noise inside the storage tank can be suppressed.

In the present embodiment, the air supply upstream portion 32 of the air supply pipe 30 is inclined so as to approach the bottom plate 20B from the tip toward the arrow R direction, but as shown in FIG. 6, it extends in the vertical direction. It may be arranged as follows. As in the present embodiment, the inclined arrangement allows drainage and air to flow smoothly in the air supply pipe 30.

Further, in the present embodiment, the intake hole 32B is formed on the upper surface side of the side wall of the air supply upstream portion 32 arranged in an inclined manner, but it is not always necessary to form the intake hole 32B on the upper surface side, and the intake hole 32B may be formed on the lower surface side. By forming the air A on the upper surface side as in the present embodiment, it is possible to prevent the air A from crossing the inside of the pipe of the air supply upstream portion 32 in the radial direction, and the drainage and the air can flow smoothly.

Further, in the present embodiment, two intake holes 32B are formed, but the number of intake holes 32B may be one or three or more. By having a plurality of intake holes 32B as in the present embodiment, the intake holes 32B can be easily formed as compared with the case where a large intake hole is used.

Further, in the present embodiment, since the opening 32A of the air supply upstream portion 32 is arranged at a position where it overlaps with the inspection port 20E in the top view, maintenance and inspection of the air supply upstream portion 32 can be easily performed from the inspection port. be able to.

10 Siphon drainage system 18A inlet, 20 storage tank, 20E inspection port 22A outlet (connection opening)
26A horizontal pulling pipe, 26B vertical pipe 30 air supply pipe, 32 air supply upstream part 32A opening, 32B intake hole 36A opening, E1 upper end

Claims (4)

A storage tank that stores the wastewater that has flowed in from the inflow port,
A horizontal pulling pipe connected to the storage tank and draining the drainage from the storage tank in the lateral direction.
A vertical pipe arranged on the downstream side of the horizontal pulling pipe and generating a siphon force by flowing down the drainage from the horizontal pulling pipe.
The opening on one end side is connected to the horizontal pulling pipe, and the opening on the other end side is arranged vertically above the connection opening of the horizontal pulling pipe to the storage tank in the storage tank. An air supply pipe that allows air to flow into the inside of the horizontal plumb pipe,
Siphon drainage system with. The siphon drainage system according to claim 1, wherein the air supply pipe has an upstream portion of air supply extending so that the opening on the other end side is the lowermost portion in the vertical direction. The siphon drainage system according to claim 2, wherein an intake hole is formed on the side surface of a pipe vertically lower than the upper end of the inflow port in the upstream portion of the air supply. The siphon drainage according to claim 2 or 3, wherein an inspection port is formed in the upper part of the storage tank, and at least a part of the upstream portion of the air supply is arranged at a position horizontally overlapping with the inspection port. system.

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