JP4559051B2 - Indoor drainage system - Google Patents

Description

The present invention relates to an indoor drainage system that forcibly pumps water drained from, for example, a sink to a drain pipe.

  Conventionally, an indoor drainage system shown in FIG. 2 is known (see Patent Document 1).

Such an indoor drainage system includes a connecting pipe 2 connected to the drain outlet 1a of the sink 1, a drain pipe 4 connected to the drainage stack 3, and water flowing through the connecting pipe 2 to the drain pipe 4. And a pump 5 forcibly pumping. And the step part 4a, 4b which stood up from the concrete slab 6 is formed in the one end side and other end side of the drain pipe 4, and waste_water | drain remains between this step part 4a, 4b. A large trap is formed between the stepped portions 4a and 4b of the drainage pipe 4 where the drainage remains, and acts as a sealing function.

The pump 5 is driven when the sensor S provided in the connecting pipe 2 detects drainage.
Japanese Patent Laid-Open No. 3-122324

However, in such an indoor drainage system, drainage is left between the stepped portions 4a and 4b of the drainage pipe 4. However, when the drainage pipe 4 is installed, there is a gap between the stepped portions 4a and 4b. There is a risk of breakage, and if the gap between the stepped portions 4a and 4b breaks, water leaks and seal water cannot be formed.

Further, when drainage is performed from the drain port 1a of the sink 1 and the sensor S detects the drainage, the pump starts to be driven, but before the pump is driven, the step 4a of the drain pipe 4 and the drain port 1a of the sink 1 are started. There is no waste water between them, and there is only air. For this reason, in the initial stage when the sensor S detects the drainage, the pump 5 is idled and the forced drainage by the pump 5 is not performed. That is, there was a problem that drainage efficiency was poor at the initial stage of drainage.

An object of the present invention is to provide an indoor drainage system that can reliably form sealed water and improve drainage efficiency even at an early stage of drainage.

In the first aspect of the present invention, a water suction port provided in a pump chamber of a pump is connected to a drain port of a drainage source, a drain pipe is connected to a discharge port of the pump chamber, and water discharged from the drain port is pumped. An indoor drainage system that forcibly pumps to a drainpipe,
The position of the outlet is higher than the position of the water inlet;
A check valve is provided at the water suction port to trap the pump chamber.

The invention of claim 2 is a pressure sensor for detecting the pressure in the trap;
And a control means for controlling the motor of the pump in accordance with the pressure detected by the pressure sensor.

According to the first and second aspects of the invention, the position of the discharge port is made higher than the position of the suction port, and a check valve is provided at the suction port to trap the pump chamber. The drainage efficiency can be improved even if the drainage remains in the pump chamber or at the initial stage of drainage.

  Embodiments of an indoor drainage system according to the present invention will be described below with reference to the drawings.

An indoor drainage system 10 shown in FIG. 1 includes a sink (discharge source) 12 of a sink 11, a pump 20 for forcibly draining water drained from the sink 12, a drain pipe 13 and the like.

One end of a connection pipe 17 is connected to the discharge port 12 </ b> A of the sink 12, and the other end of the connection pipe 17 is connected to a suction port 21 of the pump 20 via a check valve 14. Check valve 14 is connected to pipe 17
Water is allowed to flow only in one direction from the side to the pump 20 side.

The pump 20 includes a pump chamber 22, a fan 23 disposed in the pump chamber 22, and a motor 24 that rotates the fan 23. A suction port 21 is provided at the bottom of the pump chamber 22.
The discharge port 25 is provided in the upper part of the pump chamber 22. When the fan 23 rotates, water is sucked from the suction port 21, and the sucked water is discharged from the discharge port 25.

The height position of the discharge port 25 is higher than the height position of the suction port 21.
Since the check valve 14 is provided, the pump chamber 22 forms a trap, and the waste water W remains in the pump chamber 22.

A pressure sensor 27 is provided in the pump chamber 22, and the controller 30 controls the motor 24 based on the pressure detected by the pressure sensor 27. The controller 30 is disposed in the sink 11.

One end of a drain pipe 13 is connected to the discharge port 25 of the pump chamber 22, and the drain pipe 13 is connected to the floor plate 1.
5 is provided under the floor board 15 through the hole 15A. The diameter of the drain pipe 13 is the connecting pipe 17.
Is set smaller than the diameter of the floor plate and can be freely disposed between the floor plate 15 and the partition wall (concrete slab) 16. The other end of the drainage pipe 13 is connected to a drainage stack (not shown). Further, one end side portion 13A of the drain pipe 13 has a predetermined length and is substantially horizontal. This one end side portion 13A may be made ascending to increase the air bleeding.
[Operation]
Next, operation | movement of the indoor drainage system 10 comprised as mentioned above is demonstrated.

When the water in the sink 12 is drained from the discharge port 12 </ b> A to the connection pipe 17, it flows into the pump chamber 22 through the check valve 14. This inflow increases the pressure in the pump chamber 22, and the pressure sensor 27 detects the pressure. The controller 30 drives the motor 24 to rotate the fan 23 when the pressure detected by the pressure sensor 27 exceeds a preset threshold value. As the fan 23 rotates, the remaining waste water W in the pump chamber 22 is discharged from the discharge port 25.

The drainage discharged from the discharge port 25 is pumped to the drainage pipe 13 and drained to a drainage stack (not shown).

On the other hand, the remaining waste water W in the pump chamber 22 is discharged from the discharge port 25, so that the connecting pipe 1
7 is sucked into the pump chamber 22 from the suction port 21. By this suction, the connecting pipe 1
Since the water in the sink 12 is sucked through 7, the water in the sink 12 can be drained in a short time.

Since drainage W remains in the pump chamber 22 at the start of driving of the motor 24, the motor 2
Since the remaining drainage W is drained from the discharge port 25 of the pump chamber 22 without spinning, the water in the connection pipe 17 is sucked into the suction port 21 of the pump chamber 22 by this drainage. The drainage efficiency is improved even at the start of driving 24.

In addition, wastewater mixed with air flows into the pump chamber 22, but after the drainage is finished,
As time passes, the mixed air rises upward and escapes from the discharge port 25 of the pump chamber 22 to the drain pipe 13, so that the so-called air clogging state at the start of driving of the next motor 24 can be eliminated. .

Further, since the pressure sensor 27 is provided in the pump chamber 22, the surface of the pressure sensor 27 is cleaned by the water flow generated by the rotation of the fan 23. For this reason, the detection accuracy of the pressure sensor 27 can be maintained over a long period of time.

When the water is completely drained into the sink 12, the detected pressure of the pressure sensor 27 is reduced, and the controller 30 stops the driving of the motor 24 based on the decrease in the detected pressure, and the drainage is finished.

In this embodiment, the driving of the motor 24 is stopped based on the pressure detected by the pressure sensor 27. However, since the load on the motor 24 is reduced when the drainage is finished, the load on the motor 24 is detected and the load is reduced. When the voltage drops, the driving of the motor 24 may be stopped.

According to this embodiment, since the pump chamber 22 is used as a trap, there is no possibility of damaging the pump chamber 22 during piping work, so that the drainage can be reliably left in the pump chamber 22. It is possible to form the sealed water in the pump chamber 22 with certainty. Even if a water leak occurs from the pump chamber 22, the pump 20 is disposed in the sink 11, so that the water leak can be immediately recognized and dealt with promptly.

It is explanatory drawing which showed the structure of the Example of the indoor drainage system which concerns on this invention. It is explanatory drawing which showed the conventional indoor drainage system.

Explanation of symbols

10 Indoor drainage system 12 Sink (drainage source)
12A Drain port 13 Drain pipe 14 Check valve 20 Pump 22 Pump chamber 25 Discharge port

Claims (2)

A suction port provided in the pump chamber of the pump is connected to the drain port of the drainage source, a drain pipe is connected to the discharge port of the pump chamber, and the water drained from the drain port is forcibly pumped to the drain pipe by the pump An indoor drainage system,
The position of the discharge port is higher than the position of the suction port,
An indoor drainage system characterized in that a check valve is provided at the suction port to trap the pump chamber. A pressure sensor for detecting the pressure in the trap;
The indoor drainage system according to claim 1, further comprising a control unit that controls a motor of the pump in accordance with a pressure detected by the pressure sensor.

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