JP7545882B2 - Drainage pipe fittings and drainage equipment - Google Patents

Description

The present invention relates to drainage pipe fittings and drainage equipment.

Generally, buildings such as apartment buildings and office buildings are equipped with water supply and drainage facilities. The drainage facilities are typically comprised of standpipes installed vertically in the building and horizontal pipes installed horizontally on each floor.
The wastewater that flows down these vertical and horizontal pipes is collected at one or several locations by drainage pipe joints, and then discharged to a drainage facility outside the building.

In a multi-story building, a drainage system that runs vertically through the building is required. For this reason, drainage pipe joints are mainly installed in the through holes in the floor slabs of each floor. In this case, if a fire occurs in the building, smoke and toxic gases will enter the upper floors through the drainage pipe joints and standpipes.
For this reason, in order to seal the inside of the drain pipe joint in the event of a fire, the drain pipe joint is provided with a heat-expandable fire-resistant material. In the drain pipe structure described in Patent Document 1 below, the heat-expandable fire-resistant material is embedded in a recess provided on the outer surface of the drain pipe joint.

In addition, when wastewater is collected from the vertical and horizontal pipes into a drainage pipe joint, a large amount of wastewater may flow down at once. When this happens, the force of the water flowing into the drainage pipe joint causes vibrations, which then propagate to the surrounding area as drainage noise. To prevent this drainage noise from propagating into the occupancy areas of the building, sound-absorbing material is installed around the drainage pipe joint.

JP 2020-94481 A

However, when a strip of sound-absorbing material is wrapped around a drainage pipe joint, if the thermally expandable fireproof material and the sound-absorbing material overlap, problems can arise such as the inability to check the presence or absence of the fireproof material during joint manufacturing.

The present invention was made in consideration of the above-mentioned circumstances, and aims to provide a drainage pipe joint that makes it easy to check the presence or absence of thermally expandable fireproof material even when sound-absorbing material is attached.

In order to solve the above problems, the present invention proposes the following means.
The drainage pipe joint of the present invention comprises a main pipe having a depression formed on its outer surface, a heat-expandable fire-resistant material embedded in the depression, and a sound-absorbing material wrapped around the main pipe, and the joints of the sound-absorbing material in the circumferential direction of the main pipe are overlapped radially with respect to the depression.

Here, the joint of the sound-absorbing material means the overlapping part of the sound-absorbing material when both circumferential ends of the sound-absorbing material overlap in the radial direction. Also, when both circumferential ends of the sound-absorbing material are butted together in the circumferential direction (both circumferential ends of the sound-absorbing material face each other in the circumferential direction), the joint of the sound-absorbing material means the part where both ends of the sound-absorbing material are in contact with each other, or the gap between both ends of the sound-absorbing material.

According to this invention, the joints of the sound-absorbing material in the circumferential direction of the main pipe overlap radially with respect to the recess. This makes it easy to check whether or not the thermally expandable fireproof material is present by slightly turning the sound-absorbing material over.

Furthermore, at the joints of the sound-absorbing material, the circumferential ends of the sound-absorbing material may be overlapped.

Furthermore, at the joints of the sound-absorbing material, the circumferential ends of the sound-absorbing material may be butted together.

The protrusion corresponding to the recess may also be provided at an angle with respect to the axial direction of the main pipe.

According to this invention, the protrusion is inclined with respect to the axial direction of the main pipe. This causes the wastewater flowing through the main pipe to move in a spiral shape. In other words, a vortex is generated within the main pipe. This allows for more efficient drainage.

Furthermore, the recesses may be provided in multiple locations around the circumference of the main pipe.

According to this invention, multiple recesses are provided in the circumferential direction of the main pipe. This allows the amount of heat-expandable fire-resistant material embedded in the recesses to be increased. Also, multiple heat-expandable fire-resistant materials can be provided in the circumferential direction. In other words, the heat-expandable fire-resistant material can be expanded more efficiently. Therefore, in the event of a fire, the gap between the floor slab and the main pipe can be sealed more efficiently. Furthermore, if multiple protrusions are provided in the main pipe, this can have the effect of aligning the flow direction more effectively.

A sound-insulating cover may also be fixed to the outer periphery of the sound-absorbing material wrapped around the main pipe.

According to this invention, a sound-insulating cover is fixed to the outer periphery of the sound-absorbing material. This allows the sound-absorbing material to be wrapped integrally with the sound-insulating cover when wrapped around the main pipe, making it easier to join the seams.

The recess may also have a cover member made of the thermally expandable fireproof material.

According to this invention, the recess has a cover member made of a heat-expandable fire-resistant material. This makes it possible to prevent the heat-expandable fire-resistant material from falling off the drainage pipe joint during installation.

The heat-expandable fireproof material may also be shaped to fit the shape of the recess.

According to this invention, the heat-expandable fire-resistant material is shaped to fit the shape of the recess. This makes it easy to attach the heat-expandable fire-resistant material to the recess when manufacturing the drainage pipe joint.

The drainage system equipped with the above-mentioned drainage pipe joint includes a standpipe, a side branch pipe, and a drainage pipe joint, and the standpipe and the side branch pipe are connected to the main pipe.

According to this invention, the main pipe is connected to a vertical pipe and a horizontal branch pipe. This makes it possible to minimize the number of places where the drainage equipment penetrates the floor slabs on each floor. This allows for more efficient use of the space inside the building.

The present invention provides a drainage pipe joint that allows easy confirmation of the presence or absence of thermally expandable fireproof material even when sound-absorbing material is attached.

1 is a schematic diagram of a building in which a drainage pipe joint according to an embodiment of the present invention is installed. 1 is a cross-sectional view of a portion where a drainage pipe joint according to one embodiment of the present invention is installed. FIG. 1 is a perspective view of a drainage pipe joint according to an embodiment of the present invention. FIG. 2 is a perspective view showing a state in which an expandable fireproof material is attached to a drainage pipe joint according to one embodiment of the present invention. FIG. 2 is a cross-sectional view of a portion where an expandable fireproof material is attached to a drainage pipe joint according to one embodiment of the present invention. FIG. 6 is a diagram showing a state in which an outer layer member is attached to the drain pipe joint of FIG. 5, and the joint where both ends of the outer layer member are butted together in the circumferential direction does not overlap with the thermally expandable fire-resistant material in the radial direction. 6 is a diagram showing a state in which an outer layer member is attached to the drain pipe joint of FIG. 5, and the joint where both ends of the outer layer member are butted together in the circumferential direction overlaps with the thermally expandable fire-resistant material in the radial direction. FIG. 6 is a diagram showing a state in which an outer layer member is attached to the drain pipe joint of FIG. 5, and the joint where both ends of the outer layer member are overlapped in the radial direction does not overlap with the thermally expandable fire-resistant material in the radial direction. 6 is a diagram showing a state in which an outer layer member is attached to the drain pipe joint of FIG. 5, and the joint where both ends of the outer layer member are overlapped in the radial direction overlaps the thermally expandable fire-resistant material in the radial direction. 13 is a modified example of a portion where an expansive fireproof material is attached to a drainage pipe joint according to an embodiment of the present invention. 11 is a diagram showing a state in which an outer layer member is attached to the drain pipe joint of FIG. 10, and the joint where both ends of the outer layer member are overlapped in the radial direction overlaps the thermally expandable fire-resistant material in the radial direction. 11 is a diagram showing a state in which an outer layer member is attached to the drain pipe joint of FIG. 10, and the joint where both ends of the outer layer member are butted together in the circumferential direction overlaps with the thermally expandable fire-resistant material in the radial direction. This is a modification of the drain pipe joint of FIG. 5 in which a cover member is provided at the portion where the thermally expandable fireproof material is attached. FIG. 2 is a development view of the sound-insulating cover according to the embodiment of the present invention. FIG. 2 is a development view of a sound-absorbing material according to one embodiment of the present invention. The sound insulating cover shown in FIG. 14 is a modified example in which the sound insulating cover is divided into two members. FIG. 4 is a detailed view of a pipe body according to an embodiment of the present invention. This is a modified example in which a soundproof cover is provided near the water collection chamber of the drainage pipe joint in Figure 2. This is a modification in which a soundproof cover is provided near the water collection chamber of the drainage pipe joint in FIG. 2, and tape is provided on both ends of the outer layer member. This is a modified example of the drain pipe joint of FIG. 2 in which a swirl vane is provided inside the water collection chamber. This is a modification in which the stopper in FIG. 2 is provided inside the water collecting chamber.

Hereinafter, a drainage pipe joint according to one embodiment of the present invention will be described with reference to the drawings.
As shown in Fig. 1, the drainage pipe joint 100 collects wastewater flowing down from facilities on each floor (e.g., a bath 11, a washing machine 12, a sink 13) in a building 10. The collected wastewater flows down to the lower floors through a drainage standpipe 200 and is discharged to a drainage facility 20 outside the building 10.

As shown in FIG. 2, the drainage piping structure using this drainage pipe joint 100 includes a non-fire-resistant resin drainage pipe joint 100 that is installed in a through hole that vertically penetrates the floor slab S of a building, and a resin drainage standpipe (upper floor drainage standpipe 220 that allows drainage water to flow in from the upper floor and lower floor drainage standpipe 230 that allows drainage water to flow down to the lower floor) that is connected to this drainage pipe joint 100. Here, "non-fire-resistant" refers to a property that can be deformed, melted, or burned by the heat caused by a fire in a building, and an example of this is a resin-made one.

The drain pipe joint 100 and the drain riser (upper floor drain riser 220 and lower floor drain riser 230) are made of, for example, polyvinyl chloride, polyethylene, polybutene, polypropylene, nylon, etc. For the drain riser, for example, a so-called fire-resistant two-layer pipe may be used.
As shown in Figures 3 and 4, this drainage pipe joint 100 is formed of one or more (six in this example) resin injection moldings. As shown in Figures 2, 3, and 4, this drainage pipe joint 100 includes a pipe body (main pipe) 110 that is placed in the through hole of the floor slab S when installed in a building, an upper riser pipe connection part 120 that connects an upper floor side drainage riser pipe 220 that protrudes above the floor slab S and allows drainage from the upper floor to flow in, a lower riser pipe connection part 130 that protrudes below the floor slab S and connects a lower floor side drainage riser pipe 230 that protrudes below the floor slab S and allows drainage to flow down to the lower floor, and a horizontal branch pipe connection part 140 that connects a drainage horizontal branch pipe 300 above the floor slab S. A characteristic feature is that, as shown in Figures 3, 4 and 5, between the horizontal branch pipe connection portion 140 and the down rise pipe connection portion 130 in the pipe body 110, a swirling vane 114 is formed as a protrusion that protrudes from the inner surface of the pipe body 110, and a recess 112 corresponding to this swirling vane 114 is formed on the outer surface of the pipe body 110, and this recess 112 is filled with a thermally expandable fire-resistant material 116.

As shown in FIG. 2, at least a portion of the recess 112 of the swirl vane 114 is formed at a position corresponding to at least a portion of the range from the upper end to the lower end of the floor slab S when the swirl vane 114 is installed in a building.
Here, the swirl vane 114 is not limited to a swirl vane 114 as long as it is a part that changes the flow of drainage within the drainage pipe joint 100, but may be a deflector plate or the like, and is not limited to a swirl vane or a deflector plate as long as a corresponding recess 112 is formed on the outer surface of the pipe body 110.

Furthermore, it is also preferable that an outer layer member 150 having fire resistance and vibration suppression properties is provided on the outer layer of the thermally expandable fireproof material 116 so as to be wound around the outer periphery of the pipe body 110. An example of this outer layer member 150 is rock wool or glass wool.
The drainage pipe joint 100 having these characteristics will now be described in more detail.
In addition to the above-mentioned configuration, the drainage pipe joint 100 is configured such that the horizontal branch pipe connecting part 140 has three openings at 90° intervals in a plan view as shown in Fig. 3 or 4, a water collection chamber 142 having vertical ribs formed therein to prevent drainage flowing in from one horizontal drainage branch pipe 300 from flowing back into another horizontal drainage branch pipe 300, and a first horizontal branch pipe connecting member 144, a second horizontal branch pipe connecting member 146, and a third horizontal branch pipe connecting member 148 for connecting the horizontal drainage branch pipe 300 in accordance with the position of the opening. Hereinafter, the first horizontal branch pipe connecting member 144, the second horizontal branch pipe connecting member 146, and the third horizontal branch pipe connecting member 148 may be collectively referred to as the horizontal branch pipe connecting members 144, 146, and 148.

As described above, the drain pipe joint 100 is formed of six resin injection-molded products shown in Figures 3 and 4, and the joints between these separate injection-molded products shown in Figures 3 and 4 are bonded with adhesive or the like, assembled as shown in Figures 3 and 4, and further, as described above, the recess 112 is filled with thermally expandable fireproof material 116 to complete the product. In this embodiment, the pipe body 110 and the lower rise pipe connection part 130 are integrally formed to constitute one member. The horizontal branch pipe connection part 140 is formed of four members (water collection chamber 142, horizontal branch pipe connection members 144, 146, 148) as described above. The upper rise pipe connection part 120 is formed of one member. The drain pipe joint 100 is formed of the above six members. The water collection chamber 142 and the pipe body 110 may be integrally molded instead of being separate bodies. The pipe body 110 has a receiving port 111 at the upper end, a straight pipe section 115 connected to the receiving port, and a tapered pipe section 113 connected to the straight pipe section 115. The tapered pipe section narrows in diameter from top to bottom. The tapered pipe section at the lower end of the pipe body 110 is formed with a downstream riser pipe connection section 130 as a receiving port. In this embodiment, stoppers 144a, 146a, 148a, 120a are provided inside the side branch pipe connection members 144, 146, 148 and the upstream riser pipe connection section 120 to regulate the insertion amount when the drainage side branch pipe 300 and the drainage riser pipe 200 are connected (146a, 148a are not shown). The stoppers 144a, 146a, 148a regulate the insertion by hitting the ends of the drainage side branch pipe 300 and the drainage riser pipe 200 when they are inserted.

Here, the thermally expandable fireproof material 116 filled in the recess 112 will be described. The thermally expandable fireproof material 116 is formed, for example, from a resin composition containing a resin component mainly composed of butyl rubber, a phosphorus compound, neutralized thermally expandable graphite, a hydrous inorganic substance, and a metal carbonate, or a resin composition containing an epoxy resin, a phosphorus compound, neutralized thermally expandable graphite, and an inorganic filler. In particular, since the thermally expandable fireproof material 116 is filled on the outer surface of the swirling blade 114 against which the wastewater collides, it is preferable that the specific gravity is high in order to suppress the generation of vibration and noise due to the impact of the wastewater. Therefore, it is preferable that the thermally expandable fireproof material 116 contains a large amount of inorganic filler, and it is preferable that the composition of the thermally expandable fireproof material 116 contains 5% by mass or more and 70% by mass or less of inorganic filler, more preferably 10% by mass or more and 60% by mass or less, and most preferably 15% by mass or more and 50% by mass or less.

This thermally expandable fireproof material 116 is formed in a putty-like form, and is filled into the depression 112 on the outer surface of the pipe body 110 of the drain pipe joint 100 so as to fill the depression 112 up to about the outer diameter of the pipe body 110 (an amount sufficient to achieve the desired fire resistance). Therefore, the outer diameter of the pipe body 110 of the drain pipe joint 100 is about the same as that of a conventional drain pipe joint.
Alternatively, the thermally expandable fire-resistant material 116 may be pre-shaped to fit the shape of the recess 112. That is, the thermally expandable fire-resistant material 116 may be pre-shaped as a molded product to fit the shape of the recess 112, and this molded product (thermally expandable fire-resistant material 116) may be fitted into the recess 112.
In this manner, as shown in FIG. 5, the thermally expandable fire-resistant material 116 itself (not resin-containing, but pure) is filled in the portion of the recess 112 corresponding to the swirl vane 114, and as shown in FIG. 2, when the swirl vane 114 is installed in a building, at least a portion of it is formed in a position corresponding to the range from the upper end to the lower end of the floor slab S.

That is, at least a portion of the heat-expandable fireproof material 116 is interposed between the outer peripheral surface of the drain pipe joint 100 and the mortar M filled in the through hole of the floor slab S, and is further filled in the recess 112 on the back surface (outer surface side) of the swirl vane 114 that protrudes from the inner surface of the pipe body 110. Therefore, the heat-expandable fireproof material 116 is provided protruding further inward (through the swirl vane 114) than the inner wall of the pipe body 110. The pipe body 110 of the drain pipe joint 100 is inserted into the through hole of the floor slab S and fixed to the through hole by backfilling the through hole with mortar M or the like.

In a building that employs such a drainage piping structure, if the drainage piping joint 100 or the drainage standpipe (upper floor drainage standpipe 220, lower floor drainage standpipe 230) catches fire, the heat will cause the swirl vanes 114 to expand radially inward of the drainage piping joint 100, crushing the swirl vanes 114 of the drainage piping joint 100 and blocking the pipe body 110. This allows the drainage piping structure that uses this drainage piping joint 100 to shut off the pipeline so that flames, smoke, etc. do not flow in the event of a fire.

In particular, since the pre-combustion thermally expandable fire-resistant material 116 is provided further inward than the inner wall of the pipe body, i.e., it begins to expand from the swirl vanes 114 which protrude further inward than the inner wall of the pipe body 110, compared to conventional drainage pipe joints, it can effectively expand inward into the pipe body.
In addition, in this drainage pipe joint 100, a recess 112 (corresponding to the swirl vane 114) that appears on the outer surface of the pipe body 110 and that is used to form the swirl vane 114 protruding inward from the pipe body 110 is filled with a thermally expandable fireproof material 116. Therefore, compared to when the recess 112 is hollow, it is possible to reduce the vibration of the pipe body 110 when the drainage hits the swirl vane 114, thereby reducing drainage noise.

In particular, if an outer layer member 150 such as rock wool or glass wool with fire resistance and vibration suppression properties is provided on the outer layer of the heat-expandable fire-resistant material 116, the vibration suppression properties of this outer layer member 150 can further reduce drainage noise. In addition, the fire resistance properties of this outer layer member 150 can suppress the heat-expandable fire-resistant material 116 from expanding unnecessarily into the space outside the pipe body 110 in the area where the heat-expandable fire-resistant material 116 is outside the pipe body 110 and no mortar M is present (area A shown in Figure 2), so that the heat-expandable fire-resistant material 116 can be effectively expanded toward the inside of the pipe body 110.

As described above, the drain pipe joint 100 is formed from one or more resin injection molded products, and is installed by penetrating the floor slab S of a building, and can fully exert fire resistance, suppress drain noise, and suppress the increase in the pipe outer diameter. In particular, sufficient foaming properties can be exhibited by adopting a mode in which the heat-expandable fire-resistant material 116 itself is filled. In addition, since it is only necessary to fill the recess 112 on the outer surface of the pipe body 110 with the heat-expandable fire-resistant material 116, there is no increase in manufacturing costs, as with, for example, an embedded three-layer structure in which the heat-expandable fire-resistant material itself is embedded in the wall part of the pipe material, and the outer diameter of the drain pipe joint is not increased by wrapping the heat-expandable fire-resistant material itself around the outer layer of the drain pipe joint.

Next, the recess 112 in this embodiment will be described.
As shown in Fig. 5, the pipe body 110 is formed with swirl vanes 114 protruding from the inner surface of the pipe body 110. The swirl vanes 114 correspond to the recesses 112 provided on the outer circumferential surface of the pipe body 110 and are formed on the inner diameter side of the pipe body 110.

The wastewater flowing inside the pipe body 110 comes into contact with the swirl vanes 114, so that the direction of the flow of the wastewater inside the pipe body 110 is uniformly adjusted. This prevents the flow inside the pipe body 110 from being disturbed.
As shown in Figures 3 and 4, the depression 112 is provided at an incline on the outer circumferential surface of the pipe body 110. Correspondingly, the swirl vane 114 is provided at an incline inside the pipe body 110. This makes it easier for vortexes to occur when wastewater flows through the pipe body 110. Here, the fact that the swirl vane 114 is provided at an incline inside the pipe body 110 means that the swirl vane 114 has a first surface 114a that is inclined with respect to the pipe axis of the pipe body 110. The first surface 114a faces upward while inclining with respect to the axis. The first surface 114a is a surface that contacts the swirl vane 114 with the wastewater flowing down from above.

When the swirl vanes 114 are arranged parallel to the axial direction of the pipe body 110, the drainage water flowing through the pipe body 110 is aligned parallel to the axial direction of the pipe body 110. This prevents the flow inside the pipe body 110 from being disturbed. In this case, the first surface 114a extends parallel to the axial direction.

When the swirl vane 114 is arranged perpendicular to the axial direction of the pipe body 110, the swirl vane 114 can act like a canopy. This, for example, prevents wastewater from flowing into the portion of the pipe body 110 located below the swirl vane 114. In this case, the first surface 114a is perpendicular to the axial direction.

In Fig. 5, the recess 112 is provided deep at one location in the circumferential direction, and the recess 112 is provided using the entire back side of the swirl vane 114. In this case, the cross-sectional area through which the wastewater passes in the pipe body 110 may become small, and the drainage performance may be reduced. To prevent this, the recess 112 may be provided shallowly. As an example of this case, as shown in Fig. 10, the recess 112 may be provided only in a part of the back side of the swirl vane 114. That is, even on the back side of the swirl vane 114, the recess 112 is not provided in the dashed line part. That is, the recess 112 may be provided on the entire back side of the swirl vane 114, or may be provided on a part of the back side of the swirl vane 114.
Furthermore, in such a case, in order to cope with the reduction in the amount of the thermally expandable fireproof material 116 that can be filled, a plurality of recesses 112 may be provided at intervals in the circumferential direction as shown in Fig. 10. The intervals may be equal or may be determined appropriately according to the conditions of the construction site.

Next, the detailed structure of the outer layer member 150 in this embodiment will be described.
2, the pipe body 110 having the thermally expandable fireproof material 116 in the recess 112 has an outer layer member 150 on its outer periphery. In this embodiment, the outer layer member 150 has a sound absorbing material 151 and a sound insulating cover 152.

The sound absorbing material 151 is made of fibers such as glass wool, rock wool, felt, etc. The density of the fibers is preferably 40 kg/ ^m3 or more. Rock wool, which has particularly high fire resistance, is preferably used. The sound absorbing material 151 absorbs the sound associated with drainage generated inside the pipe body 110. This prevents the sound of drainage from leaking into the rooms of the building 10.
Furthermore, by attaching the sound absorbing material 151 to the tube body 110, it serves to prevent the thermally expandable fireproof material 116 provided in the recess 112 from falling off.
15, the sound absorbing material 151 is, for example, in a sheet shape. Thus, when the sound absorbing material 151 is attached to the tube body 110, it is attached by wrapping it around the tube body 110.
As described above, the sound absorbing material 151 is made of fiber. In this case, it may be difficult to connect the sound absorbing materials 151 together when wrapping and fixing the sound absorbing materials 151 around the tube body 110. In this case, a decorative layer may be provided on the outside of the tube body 110. For example, aluminum craft paper or aluminum glass cloth is preferably used as the decorative layer. This allows adhesive tape or the like to be bonded to the decorative layer. This makes it easier to connect the sound absorbing materials 151 together.

2, the sound-insulating cover 152 is provided on the outside of the sound-absorbing material 151. The sound-insulating cover 152 is made of, for example, an olefin-based elastomer such as EPDM, soft PVC, or an asphalt sheet. The sound-insulating cover 152 blocks any sound that cannot be absorbed by the sound-absorbing material 151. This makes it more difficult for drainage sounds to leak into the rooms of the building 10 and be heard.
14, the sound insulation cover 152 is, for example, in the form of a sheet. In this case, it is preferable that the sound insulation cover 152 has a cylindrical portion 152a (corresponding to the straight pipe portion 115) and a tapered portion 152b (corresponding to the tapered pipe portion 113) in accordance with the shape of the pipe body 110. In this way, when attaching the sound insulation cover 152 to the pipe body 110, the sound insulation cover 152 is attached by wrapping it around the pipe body 110.
The sound-insulating cover 152 may be formed in advance into a tubular shape to match the shape of the pipe body 110. This makes it easier to attach the sound-insulating cover 152 to the pipe body 110 compared to a sheet-shaped cover.

When attaching the sound absorbing material 151 and the sound insulating cover 152 to the pipe body 110, the sound absorbing material 151 and the sound insulating cover 152 may be fixed in advance with adhesive or double-sided tape. In this case, it is preferable that the sound insulating cover 152 is in a sheet form. This allows the outer layer member 150 to be attached to the pipe body 110 in one go, thereby shortening the work time.

Also, as shown in FIG. 16, the sound-insulating cover 152 may be divided into two parts, a cylindrical section 152a and a tapered section 152b. This allows for better adhesion to the sound-absorbing material 151.

Next, the positional relationship between the outer layer member 150 and the thermally expandable fireproof material 116 when the outer layer member 150 is attached to the pipe body 110 will be described.
6 and 7 show the cases where the ends of the outer layer member 150 attached to the pipe body 110 are butted together or separated from each other in the circumferential direction (the gap 154a between the ends in the figures is intended to more clearly show that the upper ends of the drawings do not overlap in the radial direction). When attaching the outer layer member 150 to the pipe body 110, it is normal to attach the outer layer member 150 so that the ends of the outer layer member 150 do not have a gap 154a. The gap 154a between the ends of the outer layer member 150 is caused by an error or mistake when attaching the outer layer member 150 to the pipe body 110. Alternatively, it is caused by the sound absorbing material 151 following the deformation of the sound insulating cover 152 due to thermal contraction or the like during a fire.
8 and 9 show a case where the ends of the outer layer member 150 attached to the pipe main body 110 are overlapped in the radial direction. At this time, a gap 154b is generated in the radial direction between the pipe main body 110 and the outer layer member 150 located on the outer side of the pipe main body 110.

Hereinafter, the area around the ends of the outer layer member 150 attached to the pipe main body 110 is referred to as the seam 153. Here, the seam 153a refers to the portion where the outer layer member 150 overlaps when both circumferential ends of the outer layer member 150 overlap in the radial direction. Also, the seam 153b refers to the portion where both ends of the outer layer member 150 contact each other when both circumferential ends of the outer layer member 150 are butted together in the circumferential direction (both circumferential ends of the outer layer member 150 face each other in the circumferential direction).
The seam 153 is formed over the entire axial length of the outer layer member 150. The seam 153 is generally linear and parallel to the axial direction. However, the seam 153 may extend in a direction inclined with respect to the axis when viewed from the front in which the seam 153 is viewed from the outside in the radial direction.
Since the joint 153 is likely to spread during combustion, it is preferable to connect the ends of the outer layer member 150 using a non-combustible or flame-retardant fixing member such as a metal tape such as aluminum tape or aluminum glass cloth tape, a non-combustible or flame-retardant tape made of flame-resistant acrylic fiber or glass fiber base material, a metal belt or clip, a wire mesh, a tacker, etc. Also, a decorative layer may be provided on the surface of the sound-absorbing material 151, and the decorative layers may be connected to each other using these fixing members.

Figure 6 shows a state where the joint 153b does not overlap the depression 112 provided in the pipe body 110 in any cross section perpendicular to the axial direction of the pipe body 110. Also, Figure 8 shows a state where the joint 153a does not overlap the depression 112 provided in the pipe body 110 in any cross section perpendicular to the axial direction of the pipe body 110. The arbitrary cross section means any cross section over the entire length of a partial region in the axial direction of the pipe body 110. The partial region is a region in the pipe body 110 where the depression 112 (thermally expandable fireproof material 116) is formed. The position of the upper end of the partial region is the position of the upper end of the depression 112. The position of the lower end of the partial region is the position of the lower end of the depression 112.

In other words, in Figures 6 and 8, the recess 112 is completely covered by the outer layer member 150. This makes it impossible to check the presence or absence of the thermally expandable fireproof material 116 when manufacturing the drainage pipe joint 100, etc.

For this reason, when attaching the outer layer member 150 to the pipe body 110, it is preferable to attach it so that the joint 153 and the recess 112 overlap, as shown in Figures 7 and 9. This makes it possible to easily check the presence or absence of the thermally expandable fireproof material 116 by turning over the outer layer member 150, even after the outer layer member 150 has been attached.
As shown in Figure 9, when a seam 153a is formed by overlapping the circumferential ends of the outer layer member 150, it is preferable that the central angle around the axis, which is the size along the circumferential direction of the overlapping portion of the circumferential ends, is greater than or equal to 1° and less than or equal to 10°.
Furthermore, when the seam 153a is formed by overlapping the circumferential ends of the outer layer member 150, it is preferable to attach the outer layer member 150 not simply so that the seam 153a and the recess 112 overlap, but rather so that, of both circumferential ends forming the seam 153a, the edge of the end located on the inside in the radial direction overlaps the recess 112. In this case, the thermally expandable fireproof material 116 can be immediately seen by turning over the end located on the outside in the radial direction of both circumferential ends forming the seam 153a.

3 and 4, when the depression 112 is provided at an incline in the axial direction of the pipe body 110, even if the joint 153 and the depression 112 overlap at a certain axial portion on the outer circumferential surface of the pipe body 110, they may not overlap at other axial portions. In this case, in consideration of the problem of easily checking the presence or absence of the thermally expandable fireproof material 116, it is preferable that the depression 112 overlaps with either a portion near the upper end or the lower end of the joint 153. For example, it is preferable that the overlapping range is within 5% of the entire length of the depression 112 from the upper end or the lower end of the joint 153.
In addition, inside the pipe body 110, the area below the center of the first surface 114a of the swirl vane 114 is less likely to be hit by wastewater and less likely to produce noise, i.e., vibrations are less likely to be transmitted to the floor slab S. In other words, the area above the center of the first surface 114a of the swirl vane 114 is more likely to be hit by wastewater and more likely to produce noise, i.e., vibrations are more likely to be transmitted to the floor slab S. In addition, the area above the center of the swirl vane 114 is embedded in a through hole in the floor slab S, which is important for fire resistance. For this reason, in order to prevent vibrations and sound caused by wastewater from being transmitted to the floor slab S and transmitted to the living space of the building 10, it is preferable that the vicinity of the lower end of the joint 153 overlaps with the recess 112.

Furthermore, depending on the fixing force of the outer layer member 150, a gap may occur between the pipe body 110 and the heat-expandable fire-resistant material 116, which may cause the heat-expandable fire-resistant material 116 to fall off.
In this case, if it is particularly necessary due to the conditions of the construction site, a lid member 116a is provided on the thermally expandable fireproof material 116 as shown in FIG. 13. In the illustrated example, the volume of the thermally expandable fireproof material 116 is smaller than the volume of the recess 112, and the lid member 116a is fitted into the opening of the recess 112. The surface of the lid member 116a is substantially flush with the outer surface of the pipe body 110. The lid member 116a is fixed to, for example, the inner surface (the inner peripheral surface of the opening) of the recess 112. In this case, although the thermally expandable fireproof material 116 is directly invisible due to the lid member 116a, it can be visually recognized by visually checking the lid member 116a or by performing a process of measuring the weight of the drain pipe joint 100 and the pipe body 110 after the process of providing the outer layer member 150.
The lid member 116a is made of various materials, but is preferably molded into a shape that matches the shape of the recess 112 using hard polyvinyl chloride resin, olefin resin, etc. The lid member 116a may also be made of rubber such as butyl rubber, asphalt such as rubber asphalt or modified asphalt, or an olefin-based elastomer such as EPDM molded into a sheet or cylinder, in which case it is provided around the entire circumference of the pipe body 110 in the circumferential direction, and is provided in the vertical direction within a range that includes the recess 112 in which the thermally expandable fireproof material 116 is provided.

As described above, according to the drainage pipe joint 100 of this embodiment, the joint 153 of the sound-absorbing material 151 in the circumferential direction of the pipe body 110 is overlapped radially with the recess 112. This makes it easy to check whether the thermally expandable fireproof material 116 is present by slightly turning over the sound-absorbing material 151.

The inner diameter side of the pipe body 110 has swirl vanes 114 that correspond to the recesses 112. This allows, for example, wastewater flowing inside the pipe body 110 to come into contact with the swirl vanes 114. This allows the direction of the wastewater flow inside the pipe body 110 to be uniform. This prevents the flow inside the pipe body 110 from becoming turbulent, allowing for more efficient drainage.

In addition, the inclination angle (θ1 shown in FIG. 17) of the first surface 114a inclined to the pipe axis of the pipe body 110 is preferably 10 degrees or more and 45 degrees or less, more preferably 15 degrees or more and 35 degrees or less, from the viewpoint of drainage, and can be made to flow smoothly down while swirling the drainage to secure an air core. In addition, in terms of fire resistance, the inclination angle is preferably 15 degrees or more and 45 degrees or less, more preferably 20 degrees or more and 45 degrees or less, and may be 30 degrees or more and 45 degrees or less. In this range, the range in which the thermally expandable fireproof material 116 is entangled with the sound absorbing material 151 in the event of a fire is large, so that the thermally expandable fireproof material 116 is less likely to fall off and is more likely to block the through hole of the floor slab S.
Here, θ1 is the angle between the axis of the tube body 110 and the first surface 114a when the inner surface of the tube body 110 is viewed from a direction in which the upper end of the recess 112 and the axis of the tube body 110 overlap, as shown in Figure 17.

In addition, multiple recesses 112 are provided in the circumferential direction of the pipe body 110. This allows the amount of thermally expandable fire-resistant material 116 embedded in the recesses 112 to be increased. Also, multiple thermally expandable fire-resistant materials 116 can be provided in the circumferential direction. In other words, the thermally expandable fire-resistant material 116 can be expanded more efficiently. Therefore, in the event of a fire, the gap between the floor slab S and the pipe body 110 can be sealed more efficiently. Furthermore, if multiple swirl vanes 114 are provided in the pipe body 110, the flow direction can be more regulated.

A sound-insulating cover 152 is fixed to the outer periphery of the sound-absorbing material 151. This makes it easier to join the seams 153 when wrapping the sound-absorbing material 151 around the tube body 110.

The composition of the thermally expandable fireproof material 116 contains 5% by mass or more and 70% by mass or less of inorganic filler. This minimizes the effect on the sound insulation of the pipe body 110.

The recess 112 also has a cover member made of thermally expandable fire-resistant material 116. This prevents the thermally expandable fire-resistant material 116 from falling off the drain pipe joint 100 during installation.

The heat-expandable fire-resistant material 116 is also shaped to fit the shape of the recess 112. This makes it easy to attach the heat-expandable fire-resistant material 116 to the recess 112 when manufacturing the drainage pipe joint 100.

In addition, a drainage riser 200 and a drainage horizontal branch pipe 300 are connected to the pipe body 110. This makes it possible to minimize the points where the drainage equipment penetrates the floor slab S of each floor. This allows for more effective use of the space within the building 10.

The technical scope of the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the spirit of the present invention.

For example, the inner diameter side of the pipe body 110 may not have a swirl vane 114 corresponding to the recess 112. This makes it possible to prevent the cross-sectional area inside the pipe body 110 from being reduced by the swirl vane 114 compared to when the swirl vane 114 is present. This makes it possible to make the drainage flow path wider.

The sound-insulating cover 152 does not have to be fixed to the outer periphery of the sound-absorbing material 151. This can reduce the cost of adhesives and other materials required for fixing, compared to when the sound-insulating cover 152 is fixed.

The soundproof cover 152 may also clearly indicate the position of the upper end of the pipe body 110 (i.e., the upper end of the receiving port 111). This allows the drainage pipe fitting 100 to be installed in the through hole of the floor slab S while checking the position of the upper end of the pipe body 110 relative to the upper surface of the floor slab S.

In addition, the sound-proof cover 152 may clearly indicate the distance from the top surface of the floor slab S to the bottom of the opening provided on the side of the water collection chamber 142, or the distance from the top surface of the floor slab S to the bottom of the horizontal branch pipe connecting members 144, 146, and 148.
As a result, when the water collection chamber 142 of the drainage pipe joint 100 is installed in the floor slab S at a position higher than normal, the drainage pipe joint 100 can be installed in the through hole of the floor slab S while checking the positions of the opening of the water collection chamber 142 and the horizontal branch pipe connecting members 144, 146, 148 from the upper surface of the floor slab S. Note that instead of the distance from the upper surface of the floor slab S, a mark indicating the allowable height range or limit position of the opening of the water collection chamber 142 and the horizontal branch pipe connecting members 144, 146, 148 may be used.

In addition, the thermally expandable fireproof material 116 does not have to be shaped to fit the shape of the recess 112. This allows the cost of the process to be reduced compared to when the material is shaped.

Also, as shown in FIG. 18, an upper sound insulation cover 155 may be provided around the water collection chamber 142 and the horizontal branch pipe connecting members 144, 146, 148. Here, the upper sound insulation cover 155 is a sheet-like laminate of a thin surface layer made of soft polyvinyl chloride, high-density asphalt, aluminum, or the like, and a thick sound absorbing layer made of glass wool, rock wool, felt, soft urethane foam, or the like, and the sound absorbing layer is wrapped around the water collection chamber 142 so that it is in contact with the water collection chamber 142. This can prevent the drainage sound generated in the water collection chamber 142 from leaking out.

Furthermore, the upper sound-proofing cover 155 may be separate members, with a first cover 155a for the water collection chamber 142 and a second cover 155b for the horizontal branch pipe connecting members 144, 146, and 148. Alternatively, if the requirements for sound insulation are met, the first cover 155a may not be provided. This eliminates the need to prepare an upper sound-proofing cover 155 with a special shape to match the shape of the water collection chamber 142, thereby reducing costs.

The upper sound insulation cover 155 may be partially or entirely removable from the water collection chamber 142. Furthermore, the first cover 155a covering the water collection chamber 142 and the second cover 155b covering the horizontal branch pipe connecting members 144, 146, and 148 of the upper sound insulation cover 155 may each be individually removable. It is preferable to make the upper sound insulation cover 155 removable by providing a removable member such as a fastener, a hook-and-loop fastener, or a hook at the end of the upper sound insulation cover 155. In particular, it is preferable to attach the first cover 155a to the water collection chamber 142 by connecting the ends of the cover 155a to each other with a removable member at a location where no opening is provided on the side of the water collection chamber 142.

The lower end of the upper sound-insulating cover 155 may be at the same height as the upper surface of the floor slab S. In this case, the end face of the lower end of the upper sound-insulating cover 155 faces the end face of the upper end of the outer layer member 150. At this time, the upper sound-insulating cover 155 and the outer layer member 150 may or may not be in contact with each other. This prevents the upper sound-insulating cover 155 from coming into contact with the floor slab S and mortar M. This makes it easier to carry out construction work.

Also, as shown in FIG. 19, the lower end of the upper sound insulation cover 155 may be embedded in the through hole of the floor slab S. This allows smoke that enters from the lower floor in the event of a fire to remain inside the upper sound insulation cover 155. This prevents smoke from leaking to the upper floor.

The lower part of the upper sound insulation cover 155 may be disposed between the outer layer member 150 and the water collection chamber 142. This makes it possible to prevent the outer layer member 150 from floating up due to a step that occurs between the receiving port 111 of the pipe body 110 and the water collection chamber 142.

Also, as shown in FIG. 19, the upper and lower ends of the outer layer member 150 may be fixed with tape 156. In this case, the upper end of the upper tape 156a may be buried in the through hole of the floor slab S, that is, positioned so as not to exceed the upper surface of the floor slab S. This allows smoke that has entered the interior of the outer layer member 150 in the event of a fire to remain within the upper tape 156a and mortar M. This prevents smoke from leaking to upper floors.

In addition, if the distance between the horizontal drainage branch pipe 300 and the drainage pipe joint 100 is large, the drainage gradient of the horizontal drainage branch pipe 300 cannot be achieved, and efficient drainage may not be possible. In this case, by lowering the position of the drainage pipe joint 100 so that the upper end of the upper tape 156a does not exceed the top surface of the floor slab S, it is possible to make it easier to achieve the drainage gradient of the horizontal drainage branch pipe 300.

The lower tape 156b may also be fixed to the outer surface of the downpipe connection part 130 at the bottom of the pipe body 110. This makes it difficult for smoke to enter the inside of the outer layer member 150 in the event of a fire.

If the end of the soundproofing cover 152 also serves as the tape 156, it does not need to be provided. In this case, it is preferable that the upper end of the outer layer member 150 does not exceed the upper surface of the floor slab S.

20, a swirl vane (or deflector) 114b may be provided in the water collection chamber 142. The swirl vane 114b is provided on a wall surface of the water collection chamber 142 on which the horizontal branch pipe connecting members 144, 146, 148 are not provided. In this case, the swirl vane 114b is provided integrally with the water collection chamber 142 or on another member such as the upper riser pipe connecting portion 120, so as to be at a predetermined position inside the water collection chamber 142.
The swirl vane 114b is provided either at a position facing the swirl vane 114 when viewed from above in the tube axial direction, or at a position rotated approximately 90 degrees clockwise from the swirl vane 114 when viewed from above.
When the swirl vane 114b is provided at a position facing the swirl vane 114 in a top view, the wastewater inside the pipe body 110 that does not hit the swirl vane 114 can be swirled.
In addition, if the swirl vane 114b is provided at a position rotated approximately 90 degrees clockwise relative to the swirl vane 114 when viewed from above, the wastewater that hits the swirl vane 114b will then hit the swirl vane 114, allowing an air core to be formed smoothly.
This creates a vortex inside the drain pipe, allowing water to drain more efficiently.

Also, in order to align the swirl vane 114 with the horizontal branch pipe connecting members 144, 146, 148 and to align the swirl vanes 114 with 114b, marks may be provided on the water collecting chamber 142 and the pipe body 110. The marks may be marks made by using gate cut marks made during injection molding, and are arranged so that when the water collecting chamber 142 and the pipe body 110 are combined, the gate cut marks are aligned in a straight line in the pipe axial direction.
This can improve efficiency in manufacturing the drainage pipe joint 100.

In addition, any or all of the pipe body 110, the upper riser pipe connection part 120, the lower riser pipe connection part 130, and the horizontal branch pipe connection part 140 that constitute the drainage pipe joint 100 may be made transparent. If made transparent, the drainage pipe joint 100 is preferably formed from a transparent resin such as a rigid polyvinyl chloride resin that does not contain lead stabilizers or calcium carbonate, or an ABS resin that contains methyl methacrylate.

Furthermore, any/all of the water collection chamber 142 and the side branch pipe connecting members 144, 146, 148 constituting the side branch pipe connecting portion 140 may be transparent. That is, (1) the water collection chamber 142 may be transparent and the side branch pipe connecting members 144, 146, 148 may be opaque, (2) the water collection chamber 142 may be opaque and the side branch pipe connecting members 144, 146, 148 may be transparent, or (3) both the water collection chamber 142 and the side branch pipe connecting members 144, 146, 148 may be transparent.
In the cases of (2) and (3), the same effect can be obtained even if not only the lateral branch pipe connecting members 144, 146, and 148 but also the upper riser pipe connecting portion 120 is made transparent. The cases of (1) to (3) will be described below.

(1) First, consider the case where the water collection chamber 142 is transparent and the horizontal branch pipe connecting members 144, 146, 148 are opaque. If the water collection chamber 142 is transparent, it can be seen from the outside when the water collection chamber 142 is clogged with debris, making maintenance easy. In this case, it is preferable that the upper soundproof cover 155 provided on the outer surface of the water collection chamber 142 be of a removable structure.

In particular, it is preferable to connect the ends of the upper sound insulation cover 155 with a detachable member on the side surface of the water collection chamber 142 on which no openings are provided and on which other openings are projected (in this embodiment, the surface facing the second horizontal branch pipe connecting member 146 shown in FIG. 3). The transparency and visibility of the surface on which no openings are provided and on which other openings are projected are not hindered by the horizontal branch pipe connecting members 144, 146, 148 connected to the side surface of the water collection chamber 142, the horizontal branch pipes, or the vertical ribs provided inside.

When the horizontal branch pipe connecting members 144, 146, and 148 are opaque, as shown in FIG. 20, it is preferable that the drainage horizontal branch pipe 300 is inserted into the transparent water collection chamber 142 through the opaque horizontal branch pipe connecting members 144, 146, and 148 at its end. In other words, it is preferable that the abutment portion between the stopper 144a, 146a, and 148a that restricts the insertion of the drainage horizontal branch pipe 300 and the end face of the drainage horizontal branch pipe 300 is located inside the transparent water collection chamber 142. This allows the transparent water collection chamber 142 to confirm from the outside whether the drainage horizontal branch pipe 300 has been securely inserted. At this time, it is preferable to provide the stopper 144a, 146a, and 148a on the inner surface of the water collection chamber 142 side end of the horizontal branch pipe connecting members 144, 146, and 148 so that the end of the drainage horizontal branch pipe 300 is inserted into the water collection chamber 142.

(2) Next, consider the case where the water collection chamber 142 is opaque and the horizontal branch pipe connecting members 144, 146, 148 are transparent. By making the horizontal branch pipe connecting members 144, 146, 148 transparent, it is possible to check from the outside whether the insertion amount of the drainage horizontal branch pipe 300 is sufficient. By making the upper riser pipe connecting portion 120 transparent, it is possible to check from the outside whether the insertion amount of the upper floor side drainage riser pipe 220 is sufficient. In addition, when connecting the horizontal branch pipe connecting members 144, 146, 148 to the water collection chamber 142 and the drainage horizontal branch pipe 300, or the upper riser pipe connecting portion 120 to the water collection chamber 142 and the upper floor side drainage riser pipe 220 using adhesive, it is possible to check from the outside whether the adhesive is applied appropriately.

In addition, when the water collection chamber 142 is opaque, it is preferable that the end of the drainage horizontal branch pipe 300 or the end of the upper floor drainage standpipe 220 remain outside the opaque water collection chamber 142. In other words, it is preferable that the abutment parts between the stoppers 144a, 146a, 148a, 120a that regulate the insertion of the drainage horizontal branch pipe 300 and the upper floor drainage standpipe 220 and the end faces of the drainage horizontal branch pipe 300 and the upper floor drainage standpipe 220 are located outside the opaque water collection chamber 142. This allows the insertion amount of the drainage horizontal branch pipe 300 or the upper floor drainage standpipe 220 to be confirmed from the outside by the transparent horizontal branch pipe connecting members 144, 146, 148 or the upper standpipe connecting part 120.

(3) Next, consider a case where the water collection chamber 142, the side branch pipe connecting members 144, 146, 148, and the upper riser pipe connecting portion 120 are all transparent. In this case, the inside of the water collection chamber 142 can be easily confirmed regardless of the viewing direction or height.
In addition, when the water collection chamber 142, the horizontal branch pipe connecting members 144, 146, 148, and the upper riser pipe connecting portion 120 are all transparent, it is preferable that the ends of the drainage horizontal branch pipe 300 and the upper floor side drainage standpipe 220 are retained outside the transparent water collection chamber 142. In other words, it is preferable that the abutment portions between the stoppers 144a, 146a, 148a, 120a that regulate the insertion of the drainage horizontal branch pipe 300 and the upper floor side drainage standpipe 220 and the end faces of the drainage horizontal branch pipe 300 and the upper floor side drainage standpipe 220 are located outside the transparent water collection chamber 142. As a result, the visibility of the inside of the water collection chamber 142 is not hindered by the opaque drainage horizontal branch pipe 300 and the upper floor side drainage standpipe 220, and it is easy to check the inside of the water collection chamber 142 and the connection portions between the water collection chamber 142 and the horizontal branch pipe connecting members 144, 146, 148 and the upper riser pipe connecting portion 120 from the outside.

In addition, the components in the above embodiment may be replaced with well-known components as appropriate without departing from the spirit of the present invention, and the above-mentioned modifications may be combined as appropriate.

10 Building 100 Drainage pipe joint 110 Pipe body (main pipe)
114 Swirl vane (protruding part)
116 Thermally expandable fireproof material 151 Sound absorbing material 152 Sound insulation cover 153 Joint 153a Joint 153b Joint

Claims (9)

A main pipe having a depression formed on its outer circumferential surface;
a thermally expandable fireproof material embedded in the recess;
A sound absorbing material wrapped around the main pipe;
Equipped with
The joints of the sound absorbing material in the circumferential direction of the main pipe are overlapped radially with respect to the recesses.
Drainage pipe fittings. At the joints of the sound-absorbing material, the circumferential ends of the sound-absorbing material are overlapped with each other.
2. A drain pipe joint as claimed in claim 1. At the joints of the sound-absorbing materials, circumferential ends of the sound-absorbing materials are butted against each other.
2. A drain pipe joint as claimed in claim 1. A protrusion corresponding to the recess is provided inclined with respect to the axial direction of the main pipe.
A drainage pipe joint according to any one of claims 1 to 3. A plurality of the recesses are provided in the circumferential direction of the main pipe.
A drainage pipe joint according to any one of claims 1 to 4. A sound-insulating cover is fixed to the outer periphery of the sound-absorbing material wrapped around the main pipe.
A drainage pipe joint according to any one of claims 1 to 5. The recess has a cover member made of the thermally expandable fireproof material.
A drainage pipe joint according to any one of claims 1 to 6. The thermally expandable fireproof material is shaped to fit the shape of the depression.
A drainage pipe joint according to any one of claims 1 to 7. Standpipe and
A lateral branch pipe,
A drainage pipe joint according to any one of claims 1 to 8;
Equipped with
The standpipe and the side branch pipe are connected to the main pipe.
Drainage facilities.

Images