JPH1060967A - Draining structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To efficiently lower the noise, which is generated at the time of draining, at a low cost by installing a noise insulating member in the periphery of a straight part, and installing a vibration control member in the periphery of a bent part. SOLUTION: A noise insulating sheet 5 is installed in the periphery of draining vertical pipes 1a, 1b and draining horizontal pipes 3a, 3b. A vibration control sheet 7 is installed in the periphery of a first elbow pipe 2a, a T-shaped pipe 2b, a second elbow pipe 2c, a 45 degree elbow pipe 2d and a different diameter pipe 4 of a bent part. The sheet is installed with the double-structure in the peripheral surface of the elbow pipe 2d and the different diameter pipe 4. The draining vertical pipe 1b is arranged inside of a pipe space P, and a fiber group sound absorbing material 6 is arranged inside of this pipe space P. The noise of the drained water flowing down in the straight pipe is insulated and absorbed by a noise insulating sheet 5 and a sound absorbing material 6. Furthermore, vibration of the bent part is restricted by the vibration control sheet 7. With this structure, the noise can be efficiently lowered, and while the low frequency resonance inside of the pipe space can be restricted so as to lower the noise more.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a drainage structure provided with a drainage pipe having a straight pipe portion and a bent portion, and more particularly to a drainage structure capable of efficiently and inexpensively reducing noise during drainage.

[0002]

2. Description of the Related Art Generally, in a drainage structure, a drainage pipe has a straight pipe portion formed by a vertical drainage pipe or a horizontal drainage pipe, and a bent portion formed by an elbow pipe or the like. Combined and connected.

FIG. 5 shows an example of such a conventional drainage structure. The drainage structure 100 of the related art is for discharging drainage from a toilet on the second floor to an underground drain pipe D. In the drainage structure 100, the drainage pipe has the following configuration. That is, the drainage vertical pipe 1 into which wastewater flows from the toilet
a, a first 90 ° elbow pipe 2 disposed under the second floor
a, a horizontal drain pipe 3a, a T-shaped pipe 2b connected to the ventilation pipe, a horizontal drain pipe 3b, and a second 90 ° elbow pipe 2c are sequentially connected. The second 90 ° elbow pipe 2c is connected to the vertical drainage pipe 1b provided in the pipe space P on the first floor. The drainage vertical pipe 1b is supported by support fittings S, S. The lower end of the drainage vertical pipe 1b is located under the floor of the first floor, and a 45 ° elbow pipe 2d, 2d and a different diameter pipe 4 are connected in this order to the downstream end side of the drainage vertical pipe 1b. Is connected to the underground drain pipe D.

In the drainage structure 100 described above,
Noise generated during drainage is a problem. The noise at the time of drainage has become a particularly important problem since toilets have been installed on upper floors of two or more floors in recent years. As a countermeasure against such noise at the time of drainage, techniques such as mounting of a sound insulating material or a sound absorbing material have been conventionally applied to the drainage pipe of the drainage structure 100 over the entire drainage pipe system. . Conventionally, in a residential building, Tomiji pipe (registered trademark) or the like in which a vinyl chloride pipe is coated with asbestos slate as a refractory material may be used as the drain pipe. However, although it is known that the use of the above-mentioned Tomiji tube increases the coating weight of the refractory material, the noise at the time of drainage is somewhat reduced, but the effectiveness as a sound insulation material is inferior.

[0005] As described above, the above-described technique has a problem that noise at the time of drainage is not efficiently reduced. In the pipe space P, there is also a problem that low-frequency resonance is induced and noise is increased.

SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a drainage structure capable of efficiently and inexpensively reducing noise during drainage.

[0007]

As a result of various studies, the present inventors have found that noise in a drainage structure provided with a drainage pipe having a straight pipe portion and a bent portion is caused by water flow noise inside the pipe in the straight pipe portion. Was found to be the main cause, and the impact vibration of the drainage pipe was the main cause at the bent part. In other words, the cause of noise generation is different for each part, and it has been found that it is inefficient to use only the same member for sound insulation for each part.

The present invention has been made based on the above findings. In a drainage structure provided with a drainage pipe having a straight pipe portion and a bent portion, a sound insulating member is mounted around the straight pipe portion, and the bent portion is provided. The above object has been achieved by providing a drainage structure characterized by mounting a vibration damping member around the periphery of the drainage structure. Further, the present invention provides the drainage structure according to claim 1, wherein the sound insulating member is a high specific gravity butyl rubber sheet. The present invention also provides the drainage structure according to claim 1 or 2, wherein the vibration damping member is a viscoelastic butyl rubber sheet. Further, the present invention includes the straight pipe portion supported by a support fitting in a pipe space, and a fibrous sound absorbing material is provided in the pipe space. And a drainage structure according to any one of the above. The present invention also provides a drainage structure according to any one of claims 1 to 4, wherein a vibration damping member is attached to the bent portion of the drainpipe under the floor.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the drainage structure of the present invention will be specifically described below with reference to the drawings. In addition, the drainage structure of this embodiment is a drainage structure for discharging the drainage of the toilet on the second floor to the basement. Further, in this embodiment, the same members as those of the conventional drainage structure shown in FIG. 5 are denoted by the same reference numerals, and description thereof will be omitted.

FIG. 1 is a schematic structural view showing a drainage structure according to an embodiment of the present invention, FIG. 2 is a perspective view showing a sound insulating member of the drainage structure in FIG. 1, and FIG. 3 is a perspective view showing the drainage structure in FIG. It is a graph which shows the noise level of the drainage in a drainage structure.

The drainage structure 10 of the present embodiment includes a vertical drainage pipe 1a, 1b and a horizontal drainage pipe 3a, 3b forming a straight pipe, a first 90 ° elbow pipe 2a forming a bent portion, and a T-shaped pipe. 2
b, second 90 ° elbow tube 2c, 45 ° elbow tube 2d,
2d and a different-diameter pipe 4, and the drainage is connected to the first 90 ° elbow pipe 2a, a horizontal drainage pipe 3a, and a vent pipe disposed below the floor of the second floor from the vertical drain pipe 1a. T-tube 2
b, passing through the drain horizontal pipe 3b and the second 90 ° elbow pipe 2c, flowing down the drain vertical pipe 1b, and passing through the 45 ° elbow pipes 2d, 2d and the different diameter pipe 4 under the first floor. The water is discharged to the underground drainage pipe D. Such a configuration is the same as the prior art.

In the drainage structure 10 of the present embodiment, the sound insulation sheet 5 is mounted as a sound insulation member around the drainage vertical pipes 1a and 1b and the drainage horizontal pipes 3a and 3b which are straight pipes. First 90 ° elbow tube 2a, T-shaped tube 2 which is a bent portion
b, second 90 ° elbow tube 2c, 45 ° elbow tube 2d,
A vibration damping sheet 7 is mounted as a vibration damping member around the 2d and the different diameter pipe 4. The vibration damping sheet 7 is double-mounted on the outer peripheral surfaces of the 45 ° elbow pipes 2d and 2d and the different diameter pipe 4 disposed under the floor in order to reduce the occurrence of impact vibration. The drainage vertical pipe 1b is disposed in the pipe space P, and is supported by support fittings S, S. In this pipe space P, a fibrous sound absorbing material 6 is provided.

The sound insulation member in the present invention is used to receive sound waves and reduce the energy of sound waves (transmitted waves) radiated from the back surface, and the effect depends on the size of the mass. The place to do is big. It is also important that no gap is formed during installation. The sound-insulating member (high-density butyl rubber sheet) used this time has a high-density filler (high-specific-gravity metal (lead, iron, etc.) powder) mixed into a non-vulcanized rubber sheet to achieve sound insulation performance. Is being improved.

Further, the above-mentioned vibration damping member in the present invention includes:
It is a material for suppressing vibration amplification of a natural vibration system or preventing energy accumulation in a diffusion diaphragm or the like by converting vibration energy into heat energy. In order to enhance the effect, it is important to add an appropriate mass and an elastic element to obtain a sufficient energy loss. The damping form used this time is to adhere a viscoelastic rubber sheet material (viscoelastic butyl rubber sheet) with a large loss coefficient and an appropriate thickness ratio (damping member / substrate) to the substrate, This is a non-constrained vibration damper that efficiently absorbs the energy of bending vibration generated in the base material. In FIG. 1, the hatched portion indicates the sound insulation sheet 5 attached to the straight pipe portion (the drain vertical pipes 1a, 1b, the drain horizontal pipes 3a, 3b), and the vertical line portion indicates the bent portion (first 90 ° elbow). The pipe 2a, the T-shaped pipe 2b, and the second 90-degree elbow pipe 2c) show the vibration damping sheet 7 attached thereto, and the lattice portion is a drain pipe under the floor (45-degree elbow pipes 2d, 2d, a different-diameter pipe 4).
2 shows the vibration damping sheet 7 double-mounted.

To further explain the present embodiment, as shown in FIG. 2, the sound insulating sheet 5 has a cushion member 5c made of felt or non-woven fabric fixed inside a high specific gravity butyl rubber sheet 5a having a thickness of 2 mm. It is. The sound insulation sheet 5 is formed in a tubular shape in advance, and the drainage vertical pipes 1a, 1b and the drainage horizontal pipes 3a, 3a, 3a, 3b are inserted inside the drainage vertical pipes 1a, 1b and the drainage horizontal pipes 3a, 3b. 3b is mounted on the outer peripheral surface.

The vibration damping sheet 7 is a viscoelastic butyl rubber sheet having a thickness of 6 mm (specifically, a viscoelastic butyl rubber sheet having a large loss coefficient, the same applies hereinafter). The vibration damping sheet 7 is formed in a tubular shape in advance, and the above-described 90 ° elbow pipes 2a and 2c, the T-shaped pipe 2b, and the 45 ° elbow pipes 2d and 2d are inserted inside at a piping site, whereby The 90 ° elbow pipes 2a and 2c, the T-shaped pipe 2b, and the 45 ° elbow pipes 2d and 2d are mounted on outer peripheral surfaces.

The fibrous sound absorbing material 6 is made of glass wool and extends over the entire circumference of the drainage vertical pipe 1b (partially omitted in FIG. 1) over the entire height of the side wall P 'of the pipe space P.
m thickness.

In the drainage structure 10 of the present embodiment having the above configuration, the straight pipes (the drainage vertical pipes 1a and 1b, the drainage horizontal pipe 3
a, 3b) The sound of the drainage flowing down in the inside is intercepted and absorbed by the sound insulating sheet 5 and the fiber sound absorbing material 6. The bent portions (90 ° elbow tubes 2a and 2c, T-shaped tube 2b, and 45 °
The vibration of the elbow pipes 2d, 2d and the different diameter pipe 4)
Is suppressed by The drainage of the toilet on the second floor was drained by such a drainage structure, and the noise level was measured. As a result, the noise level was 52 dB (A) and (rank N 排水 50) in the drainage structure using the Tomiji pipe (FIG. 3, the drainage structure 10 of the present embodiment is 41 dB (A), (rank N─40).
(Fig. 3) (shown by 、 in Fig. 3), and calculation (abbreviation) of the sound energy was able to be reduced to about 1/8.

As described above, according to the drainage structure 10 of the present embodiment, the main noise in the drainage structure 10 can be reduced effectively and efficiently at low cost according to the cause. According to the drainage structure 10 of the present embodiment, the fiber-based sound-absorbing material 6 in the pipe space P also avoids noise caused by low-frequency resonance in the vertical drainage pipe 1b, in addition to the noise reduction effect in the middle-high range. . According to the drainage structure 10 of the present embodiment, since the damping sheet 7 is provided on all the drainage pipes below the first floor, which is the largest cause of noise, noise is reduced efficiently and efficiently. According to the drainage structure 10 of the present embodiment, the drainage pipe (4
Since the vibration damping sheets 7 are provided on the outer peripheral surfaces of the 5 ° elbow pipes 2d and 2d and the different-diameter pipes 4), noise is reduced particularly favorably and efficiently.

The present invention is not limited to the embodiments described above, and specific shapes, dimensions, and the like of each member can be appropriately changed without departing from the spirit of the present invention. For example,
The sound insulation member does not necessarily have to be a high specific gravity butyl rubber sheet, but a high specific gravity vinyl chloride sheet or a lead sheet,
It may be a thin iron plate or a copper plate. However, a high-density butyl rubber sheet is preferred from the viewpoint of workability and noise reduction effect in view of cost. When a high-density butyl rubber sheet is used, the thickness is preferably about 2 mm from the viewpoint of cost and noise reduction, but is not limited thereto. Further, the cushion member 5c is preferably provided from the viewpoint of simplicity at the time of mounting, but need not be provided.

As shown in FIG. 4, the sound insulation member is a high-density butyl rubber sheet-like sound insulation member 15 having adhesive portions 15b, 15b on one side of the surface facing each other.
A release paper is adhered and protected on the adhesive portions 15b, 15b, and the release paper is peeled off at the piping site to remove the adhesive portion 15b.
b and 15b are exposed and wound around the outer peripheral surfaces of the vertical drainage pipes 1a and 1b and the horizontal drainage pipes 3a and 3b, and one adhesive portion 15b
To the straight pipe section (vertical drain pipes 1a, 1b, horizontal drain pipes 3a, 3b)
Alternatively, the other may be adhered and fixed to the other surface of the sound insulating member 15.

The vibration damping member is not necessarily a viscoelastic butyl rubber sheet, but may be a lead sheet, a viscous resin sheet, oil clay, or the like. However, it is preferable to use a viscoelastic butyl rubber sheet from the viewpoint of workability and noise reduction effect in view of cost. When a viscoelastic butyl rubber sheet is used, the thickness is preferably about 6 mm from the viewpoint of cost and noise reduction, but is not limited to this. The vibration damping member is formed as a spreadable sheet-shaped member having an adhesive portion, and includes a bent portion (90 ° elbow tube 2a, 2c, T-shaped tube 2b, and 45 ° elbow tube 2).
d, 2d, wound or crimped on the outer peripheral surface of the different diameter pipe 4),
It can be made to stick and fix by the above-mentioned sticking part.

Although the fiber-based sound absorbing material 6 is not provided, a sufficient noise reduction effect can be obtained to some extent. However, in order to avoid a resonance phenomenon occurring in the pipe space P and obtain a further noise reduction effect. Preferably has a fiber-based sound absorbing material 6. The fiber-based sound absorbing material 6 may be rock wool, cellulose fiber, felt, or the like as a fiber-based sound absorbing material other than glass wool, but glass wool is preferable from the viewpoint of workability. Straight pipe (drain vertical pipe 1
a, 1b, drain horizontal pipes 3a, 3b), bent portions (90 ° elbow pipes 2a, 2c, T-shaped pipe 2b, 45 ° elbow pipes 2d, 2)
d, The different diameter pipes 4) do not necessarily need to be connected by the above combination. Drainage structure to discharge drainage generated on the second floor to the basement as well as drainage from the first floor or three or more floors, drainage structure to discharge not to underground drainage pipe D but to the ground However, the present invention is particularly useful in a drainage structure in which drainage from the second floor or more is discharged to the underground.

[0024]

As described above, according to the drainage structure according to any one of claims 1 to 3, noise in the straight pipe portion is cut off by the sound insulating member, and vibration in the bent portion is suppressed by the vibration damping member. Therefore, it is possible to efficiently reduce noise in the drainage structure for each cause.

According to the drainage structure of the fourth aspect, in addition to the above-described effects, low-frequency resonance in the pipe space is suppressed by the fibrous sound absorbing material, so that noise can be further reduced. .

According to the drainage structure of the fifth aspect, the noise is satisfactorily reduced in the drain pipe under the floor, which causes the noise most.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram showing one embodiment of a drainage structure of the present invention.

FIG. 2 is a perspective view showing a sound insulating member of the drainage structure of FIG.

FIG. 3 is a graph showing the noise level of drainage in the drainage structure of FIG. 1 and the drainage structure of the prior art.

FIG. 4 is a plan view and a perspective view showing another example of the sound insulating member of the drainage structure of FIG.

FIG. 5 is a schematic configuration diagram showing an example of a conventional drainage structure.

[Explanation of symbols]

 1a Drainage vertical pipe (straight pipe part) 1b Drainage vertical pipe (straight pipe part) 2a First 90 ° elbow pipe (bent part) 2b T-shaped pipe (bend part) 2c Second 90 ° elbow pipe (bend part) 2d 45 ° elbow pipe (bending part) 3a Drain horizontal pipe (straight pipe part) 3b Drain horizontal horizontal pipe (straight pipe part) 4 Different diameter pipe 5 Sound insulation sheet (sound insulation member) 6 Fiber sound absorbing material 7 Damping sheet (vibration suppression) 10) Drainage structure 15 Sound insulation member D Underground drain pipe P Pipe space P 'Side wall S Support bracket

Claims (5)

[Claims] In a drainage structure provided with a drain pipe having a straight pipe portion and a bent portion, a sound insulation member is mounted around the straight pipe portion, and a vibration damping member is mounted around the bent portion. Characteristic drainage structure. 2. The drainage structure according to claim 1, wherein the sound insulation member is a high specific gravity butyl rubber sheet. 3. The drainage structure according to claim 1, wherein the damping member is a viscoelastic butyl rubber sheet. 4. The apparatus according to claim 1, further comprising: the straight pipe portion supported by a support fitting in a pipe space, wherein a fiber-based sound absorbing material is disposed in the pipe space. The drainage structure according to any one of the above. 5. The drainage structure according to claim 1, wherein a vibration damping member is attached to the bent portion of the drainpipe under the floor.