JP7024164B2 - Drainage port member and drainage piping structure - Google Patents

Description

The present invention relates to a drainage port member and a drainage pipe structure.

A concave drainage port member is provided on the bottom surface of the kitchen sink. Conventionally, the internal diameter of a general drainage port member is set to be equal to or smaller than the inner diameter of the upper inlet (see, for example, Patent Document 1).

JP-A-2015-101871

However, when an attempt is made to apply a drainage port member as described in Patent Document 1 to a siphon drainage system, the drainage that could not be completely discharged from the drainage port member until the siphon is effective overflows from the drainage port member. There was a case that it ended up.

An object of the present invention is to provide a drainage port member capable of suppressing the overflow of drainage and a drainage pipe structure.

The drainage port member according to the first aspect includes a concave drainage port main body having an inlet opening at an upper portion and an outlet opening at a side portion, and at least a part of the internal space of the drainage port main body is the flow. It has a horizontal cross-sectional area larger than the opening area of the entrance.

The drainage port member according to the first aspect has an internal space having a horizontal cross-sectional area larger than the opening area of the inflow port, at least in a part thereof. Therefore, the drainage port member according to the first aspect has a drainage port member having an internal space having a horizontal cross-sectional area equivalent to the opening area of the inflow port (in other words, a horizontal direction larger than the opening area of the inflow port). Compared to (which does not have a cross-sectional area portion), the volume of the internal space can be increased without changing the height (horizontal dimension).

Therefore, the drainage port member according to the first aspect is compared with a drainage port member having an internal space having a horizontal cross-sectional area equivalent to the opening area of the inflow port when a large amount of water is flowed at one time. , A large amount of drainage can flow into the inside, and it is possible to prevent the drainage from overflowing from the inflow port.

As an example, the drainage port member according to the first aspect includes a first water circulation device, a first drainage trap provided on the downstream side in the drainage direction of the first water circulation device, and the first drainage trap. A second drainage device provided separately from the water supply device, a second drainage trap provided on the downstream side in the drainage direction of the second water supply device, and a drainage direction downstream of the first drainage trap. It can be provided in the first water circulation device of the drainage pipe structure provided with a merging member for merging the side and the downstream side in the drainage direction of the second drainage trap.

By the way, in this drainage piping structure, when drainage is discharged from the second water circulation device, the air between the second drain trap and the confluence is pushed until the drainage reaches the confluence. The pressure inside the pipe rises. This pressure acts not only on the drainage downstream side of the merging portion via the merging portion but also on the first drain trap side from the merging portion. If the pressure acting on the first drain trap side is large, the first drain trap may be broken and the air in the drain pipe may be discharged to the first water circulation device side.

Since the drainage port member according to the first aspect has an internal space having a horizontal cross-sectional area larger than the opening area of the inflow port, the drainage port member has a horizontal cross-sectional area equivalent to the opening area of the inflow port. Compared to the drainage port member having an internal space, the volume of the internal space can be increased, and the vertical dimension, in other words, the height dimension can be shortened.

Therefore, the height dimension of the flow path from the first drain trap of the drain outlet member to the confluence portion can be increased by the amount of shortening the height dimension of the drain outlet member. As a result, the volume of the flow path from the first drain trap to the confluence can be increased, and when the drainage is discharged from the second water supply device, the first drain trap reaches the confluence. It is possible to alleviate the pressure increase that occurs in the flow path up to and suppress the breakage of the first drain trap.

The drainage piping structure according to the second aspect is provided in the first water circulation device to which the drainage port member according to the first aspect is attached and on the downstream side in the drainage direction of the first water circulation device. A drainage trap, a second drainage device provided separately from the first water supply device, and a second drainage trap provided on the downstream side in the drainage direction of the second water supply device. A merging member for merging the downstream side of the first drainage trap in the drainage direction and the downstream side of the second drainage trap in the drainage direction is provided, and the pipe volume from the merging member to the first drainage trap is set. It is set in a range equal to or larger than the pipe volume from the merging member to the second drainage trap.

In the drainage pipe structure according to the second aspect , the drainage from the first water supply device is discharged to the downstream side through the drainage port member, the first drain trap, and the merging member according to the first aspect . The drainage from the second water supply device is discharged to the downstream side through the second drain trap and the merging member.

When the drainage is discharged from the second water circulation device, the air between the second drain trap and the confluence is pushed until the drainage reaches the confluence, and the pressure in the pipe rises. This pressure acts not only on the drainage downstream side of the merging portion via the merging portion but also on the first drain trap side from the merging portion. If the pressure acting on the first drain trap side is large, the first drain trap may be broken and the air in the drain pipe may be discharged to the first water circulation device side.

Here, in the drainage pipe structure described in the second aspect , the pipe volume from the merging member to the first drain trap is set to a range equal to or larger than the pipe volume from the merging member to the second drain trap, and the merging. Since the piping volume from the member to the first drain trap is set larger than the piping volume from the merging member to the second drain trap, it merges when the drainage is discharged from the second water circulation device. It is possible to alleviate the pressure increase generated in the flow path on the first drain trap side from the portion and suppress the breakage of the first trap.

Here, when the pipe volume from the merging member to the first drain trap is less than 1.0 times the pipe volume from the merging member to the second drain trap, the rupture of the first drain trap is suppressed. Becomes difficult.

In order to suppress the breakage of the first drain trap, it is sufficient that the piping volume from the merging member to the first drain trap is 1.0 times the piping volume from the merging member to the second drain trap. Is. If the pipe volume from the merging member to the first drain trap exceeds twice the pipe volume from the merging member to the second drain trap, the pipe length from the merging member to the first drain trap is longer than necessary. It becomes long and wasteful use of piping members, and for example, it becomes difficult to fit the piping under the water-related equipment.

In the invention described in the third aspect , in the drainage pipe structure according to the second aspect , the pipe length from the merging member to the first drain trap is the pipe length from the merging member to the second drain trap. Is set longer than.

In the drainage pipe structure according to the third aspect , since the pipe length from the merging member to the first drain trap is set longer than the pipe length from the merging member to the second drain trap, the first from the merging portion. The volume of the flow path leading to the drain trap can be increased more than the volume of the flow path leading from the confluence to the second drain trap.

According to the drainage port member according to the present invention, there is an excellent effect that the overflow of drainage can be suppressed.
Further, according to the drainage pipe structure according to the present invention, there is an excellent effect that the overflow of drainage can be suppressed.

It is a side view which shows the outline of the drainage pipe structure which concerns on 1st Embodiment of this invention. (A) is a vertical sectional view showing a drainage port member used in the drainage system according to the first embodiment, and (B) is a bottom view showing a drainage port member shown in FIG. 2 (A). (A) is a plan view showing an inflow portion (opening area), and (B) is a horizontal sectional view showing a tubular portion including a protruding portion of a drainage port member (3B-3B line cross section of FIG. 2A). Figure). (A) is a perspective view showing a part of the pressure relaxing device and the pipe joint as a cross section, and (B) is a horizontal sectional view of the pressure relaxing device (cross section 4B-4B in FIG. 4 (A)). Figure). It is a perspective view which shows the bag body. It is a side view which shows the outline of the drainage pipe structure which concerns on a conventional example. It is a side view which shows the outline of the drainage pipe structure which concerns on 2nd Embodiment of this invention. It is a perspective view which made a part which shows the pressure relaxation apparatus used for the drainage pipe structure which concerns on 2nd Embodiment of this invention, and a pipe joint. It is a side view which shows the outline of the drainage pipe structure which concerns on 3rd Embodiment of this invention. (A) is a vertical sectional view showing a drainage port member used for the drainage pipe structure according to the fourth embodiment, and (B) is a plan view showing the drainage port member shown in FIG. 10 (A). (A) is a vertical sectional view showing a drainage port member used for the drainage pipe structure according to the fifth embodiment, and (B) is a plan view showing the drainage port member shown in FIG. 11 (A). It is a perspective view which shows the split nut used when attaching the drainage port member used for the drainage pipe structure which concerns on 5th Embodiment. (A) is a perspective view which shows the confluence pipe used for the drainage pipe structure which concerns on 5th Embodiment, and (B) is a plan view which shows the confluence pipe.

[First Embodiment]
The drainage pipe structure 10 according to the first embodiment of the present invention will be described with reference to FIGS. 1 to 5.
(Drainage system)
A so-called siphon drainage system is used in the drainage pipe structure 10 according to the present embodiment. As shown in FIG. 1, a drainage joint 18 for flowing drainage from a water supply device (sink 22, dishwasher 26), which will be described later, is provided in the drainage stand pipe 16 that penetrates the through hole 14 of the floor slab 12 of the building. It is provided so as to combine the drainage from the upper drainage stand 16 and the drainage from the water supply device.

On each floor, floors 20 are arranged at intervals above the floor slab 12. On the floor 20, a sink 24 for a kitchen equipped with a sink 22 as an example of a first water-related device and a dishwasher 26 as an example of a second water-related device are installed. ..

(Drainage port member)
As shown in FIGS. 1 and 2, the bottom portion 22A of the sink 22 is provided with a drainage port member 28 through which drainage flows. As shown in FIG. 2A, the drainage port member 28 includes a tubular portion 28A as an example of the drainage port main body. The tubular portion 28A is integrally provided on the lower side portion of the cylindrical portion 28Aa and the cylindrical portion 28Aa whose axial direction is oriented in the vertical direction, and is provided on one side of the cylindrical portion 28Aa in the radial direction (horizontal direction) (FIG. 2). A protruding portion 28Ab is provided on the left side of the drawing. The lower portion of the cylindrical portion 28Aa and the protruding portion 28Ab is closed by the bottom portion 28B.

As shown in FIG. 2B, the protruding portion 28Ab of the present embodiment has a tapered shape in which the shape looking up from the lower side becomes narrower toward the left side of the drawing. A tubular outlet 28C is formed on the tip end side of the protrusion 28Ab. A male screw 30 for connecting to an elbow 38, which will be described later, is formed on the outer peripheral surface of the tubular outlet 28C.

A cylindrical neck portion 28D having a diameter larger than that of the cylindrical portion 28Aa is provided on the upper portion of the cylindrical portion 28Aa, and a male screw 32 is formed on the outer peripheral surface of the neck portion 28D. An annular flange 28E is formed at the upper end of the neck portion 28D. The opening portion inside the annular flange 28E is the inflow port 29 into which the drainage of the sink 22 flows.

Since the drainage port member 28 of the present embodiment is integrally provided with a projecting portion 28Ab extending in the horizontal direction on the lower side portion of the cylindrical portion 28Aa, the inside of the tubular portion 28A is formed in the horizontal direction of the opening portion. A portion having a cross-sectional area B (see the diagonally upward-sloping portion of FIG. 3B) larger than the cross-sectional area A (see the diagonally upward-sloping portion of FIG. 3A) is formed.

Therefore, the volume of the drainage port member 28 is increased when the protruding portion 28Ab is not formed, in other words, as compared with the case where a cylindrical portion 28Aa having a constant diameter is formed up to the bottom portion 28B of the tubular portion 28A. Can be done. When the drainage port member 28 is used in a general household, it is preferable to secure a volume of about 2500 ml (milliliter) to 3000 ml.

As shown in FIG. 2A, the drainage port member 28 is formed in the sink 22 by sandwiching the packing 36 and the bottom portion 22A of the sink 22 between the nut 34 screwed into the male screw 32 and the flange 28E. It is fixed.

A round hole 37 for attaching the drainage port member 28 is formed in the bottom portion 22A of the sink 22, and the diameter of the round hole 37 allows the tubular portion 28A of the drainage port member 28 to be inserted from above. The diameter is set to be slightly larger than the outer diameter of the male screw 32 of the neck 28D.

Further, the cylindrical portion 28Aa of the drainage port member 28 has a diameter smaller than the inner diameter of the nut 34, and the protruding portion 28Ab is formed to have a size that can be inserted into the nut 34. Therefore, as shown by the two-dot chain line in FIG. 2A, the nut 34 can be inserted from the outlet 28C side and screwed into the male screw 32 of the neck portion 28D.

As shown in FIG. 1, a water-sealed S-shaped trap 40 as an example of a trap is connected to the outlet 28C of the drainage port member 28 via an L-shaped elbow 38 as an example of a drainage pipe. There is.

(S-shaped trap)
The S-shaped trap 40 includes a U-shaped first bent portion 40A and an inverted U-shaped second bent portion 40B formed on the downstream side of the first bent portion 40A in the drainage direction. .. In the S-shaped trap 40 of the present embodiment, the second bent portion 40B is formed to have a smaller diameter than the first bent portion 40A. A part of the drainage is stored in the first bent portion 40A as sealing water.

A cylindrical cleaning port 42 is provided at the lower end of the first bent portion 40A. A male screw portion (not shown) is formed on the outer periphery of the cleaning port 42. The cover 44 is attached to the cleaning port 42 by screwing the female threaded portion (not shown) of the cover 44 into the male threaded portion.

Further, a vent valve mounting portion 46 opened upward is provided at the upper end of the second bent portion 40B, and the vent valve 48 is attached to the vent valve mounting portion 46. The vent valve 48 is a component for allowing air from the outside to pass through the S-shaped trap 40 and preventing drainage and air from passing through the S-shaped trap 40 to the outside.

(Piping joints, pressure relaxation devices)
A pipe joint 50 is provided on the downstream side of the S-shaped trap 40 in the drainage direction. The pipe joint 50 is a member that connects the pressure relaxation device 64 to the S-shaped trap 40.
As shown in FIGS. 1 and 4A, the pipe joint 50 includes a main pipe portion 52 extending in the vertical direction and a branch pipe portion 54 inclined in the vertical direction, and has a substantially Y shape. Is formed in.

A large diameter portion 52A having a larger diameter than the general portion is formed in the lower portion of the main pipe portion 52, and a vertical portion 78A of the L-shaped pipe 78 on the downstream side, which will be described later, is inserted into the large diameter portion 52A. A nut 58 (see FIG. 1) is screwed into a male screw portion 56 formed on the outer peripheral surface of the diameter portion 52A so as to be connected to the vertical portion 78A of the L-shaped pipe 78.

Further, a large diameter portion 52B having a larger diameter than the general portion is also formed on the upper portion of the main pipe portion 52, and the second bent portion 40B of the S-shaped trap 40 is inserted into the large diameter portion 52B, and the large diameter portion is formed. The nut 62 (see FIG. 1) is screwed into the male screw portion 60 formed on the outer peripheral surface of the 52B so that it can be connected to the S-shaped trap 40.

As shown in FIG. 4A, a pressure relaxation device 64 is provided at the upper end of the branch pipe portion 54 in the pipe joint 50. The pressure relaxation device 64 is a component for relaxing the pressure acting on the S-shaped trap 40.

As shown in FIGS. 4 (A) and 4 (B), the pressure relaxation device 64 has a bag body 66 communicating with the branch pipe portion 54 of the pipe joint 50 and a cup-shaped cover 68 covering the bag body 66. I have.

The bag 66 is made of an elastic material such as rubber, and is formed in a cylindrical shape with one end closed and the lower open as shown in FIGS. 4 and 5. As shown in FIG. 4B, the bag body 66 is formed in a shape extending outward from the central portion in a plan view. The bag body 66 can be elastically expanded and contracted in the lateral direction (outside the radial direction of the cover 68), and when positive pressure is received from the L-shaped pipe 78 on the downstream side, the bag body 66 elastically deforms and swells in the lateral direction. , The pressure generated in the L-shaped pipe 78 is configured to be relieved.

As shown in FIG. 4A, the end of the branch pipe portion 54 in the pipe joint 50 is a large-diameter cylindrical mounting portion 70, and the bag body 66 and the cover 68 are mounted on the mounting portion 70. Has been done.

A male screw portion 72 for mounting is formed on the outer periphery of the mounting portion 70, and a female screw portion 74 for mounting is formed on the inner peripheral surface of the lower end portion of the cover 68. By screwing the mounting female screw portion 74 into the mounting male screw portion 72, the bag body 66 and the cover 68 are attached to the mounting portion 70.

A plurality of ventilation holes 76 are formed on the top surface 68A of the cover 68. As a result, the change in the internal pressure inside the cover 68 can be suppressed.

As shown in FIG. 1, an L-shaped pipe 78 is provided on the downstream side of the pipe joint 50. The L-shaped pipe 78 includes a vertical portion 78A extending along the vertical direction, a horizontal portion 78B extending along the horizontal direction, and a curved portion 78C connecting the vertical portion 78A and the horizontal portion 78B.

(Combined pipe)
A merging pipe 80 as an example of a merging member is connected to an end portion of the L-shaped pipe 78 on the downstream side in the drainage direction of the horizontal portion 78B. The merging pipe 80 has a horizontal pipe portion 80A extending in the horizontal direction and a vertical pipe portion 80B extending in the upward direction, and has a T-shape in a side view. Are merged and discharged to the downstream side.

The dishwasher 26 is provided with a trap 82 via a pipe 84 arranged horizontally above the bottom plate 24A of the sink 24 and extending horizontally, an elbow 86, and a pipe 88 extending downward. , It is connected to the vertical pipe portion 80B of the merging pipe 80.

A horizontal pulling pipe 90A of the siphon drainage pipe 90 is connected to the end of the confluence pipe 80 on the downstream side in the drainage direction. The siphon drain pipe 90 includes a horizontal pull pipe 90A extending in the horizontal direction, a vertical pipe 90B extending in the vertical direction, and an L-shaped drop pipe 90C connecting the horizontal pull pipe 90A and the vertical pipe 90B. .. The vertical pipe 90B is connected to the drainage stand pipe 16 via the drainage joint 18.

The siphon drainage pipe 90 generates a siphon force by causing the drainage flowing from the horizontal pull pipe 90A to the vertical pipe 90B to flow downward in a full flow state. The siphon force toward the discharge direction acts on the drainage on the upstream side of the horizontal pull pipe 90A and the horizontal pull pipe 90A by being pulled by the siphon force generated in the vertical pipe 90B.
In the present embodiment, in order to efficiently generate the siphon force, the pipe diameter of the pipe on the downstream side of the S-shaped trap 40 is set to 20 A as an example, but the pipe diameter is not limited to this.

(Action)
The drainage pipe structure 10 according to the present embodiment is configured as described above, and its operation will be described below.
When drainage is drained to the sink 22, the drainage is siphon drainage via the drainage port member 28, the elbow 38, the S-shaped trap 40, the main portion 52 of the pipe joint 50, and the L-shaped drainage pipe 78. It flows into the pipe 90.

In the siphon drainage pipe 90, the siphon force is generated by the drainage flowing into the vertical pipe 90B flowing downward in a full flow state, and the siphon force can quickly drain the drainage on the upstream side to the downstream side. It takes a certain amount of time from when the drainage is drained to the drainage port member 28 until the siphon force is generated.

Therefore, in the drainage pipe structure 10 using the siphon drainage pipe 90, the drainage capacity (drainage amount per unit time) is smaller until the siphon force is generated than when the siphon force is generated. In other words, if a large amount of drainage is drained to the sink 22 at one time, the drainage capacity cannot keep up with the drainage capacity at the initial stage of drainage, and the drainage may overflow from the drainage port member 28.

The drainage pipe structure 10 according to the present embodiment has a bowl-shaped shape having a constant diameter from the opening to the bottom or a small diameter from the opening to the bottom, as compared with a conventional general drainage port member. Since the volume of the drainage port member 28 can be increased, the drainage from the drainage port member 28 can be discharged from the drainage port member 28 by quickly accepting the drainage from the reservoir to the drainage port member 28 and temporarily increasing the apparent drainage capacity. It is possible to suppress the overflow. In other words, the drainage port member 28 having an expanded volume serves as a buffer for temporarily storing a large amount of drainage discharged at one time.

When used in a general household, it is preferable that the volume of the drainage port member 28 is secured to be about 2500 ml (milliliter) to 3000 ml. If the volume is less than 2500 ml, the volume as a buffer may be insufficient in the case of a reservoir flow, and it may not be possible to prevent the drainage from overflowing from the drain port member 28.

After that, when the vertical pipe 90B is filled with drainage and a siphon force is generated in the vertical pipe 90B, the drainage on the upstream side of the siphon drainage pipe 90 is sucked by the siphon force and efficiently discharged to the downstream drainage stand pipe 16. Therefore, the drainage temporarily accumulated inside the drainage port member 28 is also quickly discharged.

The internal space of a conventional general drainage port member has a bowl-shaped shape having a constant diameter from the opening to the bottom or a small diameter from the opening to the bottom, and has a depth compared to the diameter of the opening. Generally, the size is small (see, for example, Japanese Patent Application Laid-Open No. 2015-101871).

Therefore, as shown in FIG. 6, a drainage pipe structure 200 using a drainage port member 202 having a constant diameter in the vertical direction and an increased height H (diameter D <height H) to increase the volume is considered. Be done. However, when the drainage port member 202 having such a high height H is used, the vertical dimension of the space for storing cooking utensils such as pots and other articles is shortened below the drainage port member 202. As a result, the space for storing cooking utensils such as pots and other items is reduced under the drainage port member 202.

On the other hand, in order to increase the volume of the drainage port member 28 of the present embodiment, as shown in FIG. 1, instead of increasing the height H, the lateral dimension (dimension in the left-right direction of the drawing) is lengthened. Therefore, it is possible to secure the vertical dimension of the space provided below the drainage port member 28 (compared to the example of FIG. 6), and under the drainage port member 28, cooking utensils such as pots, etc. It is possible to secure a space for storing the goods.

Further, since it is not necessary to increase the diameter of the upper part of the tubular portion 28A in order to increase the volume of the drainage port member 28, the diameter of the round hole 37 formed in the bottom portion 22A of the sink 22 to which the drainage port member 28 is attached is expanded. You don't even have to. In other words, the round hole 37 may have the same dimensions as those formed in the existing sink.

As described above, in the drainage port member 28 of the present embodiment, the protruding portion 28Ab is projected horizontally from the side portion of the cylindrical portion 28Aa to expand the volume, so that the structure is simple without increasing the number of parts. Therefore, the overflow of the drainage from the drainage port member 28 can be suppressed.

Further, according to the structure of the drainage port member 28 of the present embodiment, it is possible to reduce the vertical dimension, in other words, the height dimension of the drainage port member 28 while increasing the volume of the internal space. Thereby, the height dimension of the flow path from the outlet 28C of the drainage port member 28 to the confluence pipe 80, for example, the length of the vertical portion 78A of the L-shaped pipe 78, and the height of the drainage port member 28. By shortening H, the volume of the flow path from the S-shaped trap 40 (the liquid level of the sealed water on the downstream side of the first bent portion 40A) to the confluence pipe 80 can be increased.

When the drainage is discharged from the dishwasher 26, the air between the trap 82 of the dishwasher 26 and the merge pipe 80 is pushed until the drainage reaches the confluence pipe 80, and the pressure in the pipe rises. .. This pressure acts not only on the drainage downstream side (drainage stand pipe 16 side) of the merge pipe 80 via the merge pipe 80, but also on the drainage direction upstream side, that is, the S-shaped trap 40 side. If the pressure acting on the S-shaped trap 40 side is large, the S-shaped trap 40 may be broken and the air in the drain pipe may be discharged to the sink 22 through the drain port member 28.

However, as described above, by increasing the volume of the flow path from the S-shaped trap 40 to the confluence pipe 80, in other words, the air volume, when the drainage is discharged from the dishwasher 26, the S-shaped trap The pressure increase acting on the 40 can be alleviated, and the S-shaped trap 40 can be suppressed from being broken.

The volume in the pipe from the merging pipe 80 to the S-shaped trap 40 (the liquid level of the sealing water on the downstream side of the first bent portion 40A) is the volume in the pipe from the merging pipe 80 to the trap 82 of the dishwasher 26 (sealing on the downstream side). It is preferable to set the volume in the range of 0.4 to 0.6 times the volume in the pipe up to the liquid level of water).

If the volume in the pipe from the combined pipe 80 to the S-shaped trap 40 is less than 0.4 times the volume in the pipe from the combined pipe 80 to the trap 82 of the dishwasher 26, the pressure relaxation effect is insufficient and the S-shaped trap is obtained. It becomes difficult to suppress the breakage of the trap 40.

On the other hand, when the volume in the pipe from the combined pipe 80 to the S-shaped trap 40 exceeds 0.6 times the volume in the pipe from the combined pipe 80 to the trap 82 of the dishwasher 26, the pressure relaxation effect becomes high. However, the pipe from the combined pipe 80 to the S-shaped trap 40 is unnecessarily lengthened.

[Second Embodiment]
The drainage pipe structure 10 according to the second embodiment of the present invention will be described with reference to FIGS. 7 and 8. The same components as those in the first embodiment are designated by the same reference numerals, and the description thereof will be omitted.
As shown in FIG. 7, in the drainage pipe structure 10 of the present embodiment, the pressure relief device 64 is connected to the intermediate portion of the pipe 84 via a T-shaped joint 92 and a pipe joint 94.

The pipe joint 94 includes a straight pipe portion 98 extending in the vertical direction and a funnel portion 100 whose diameter gradually increases upward, and a mounting male screw portion 102 formed on the outer periphery of the funnel portion 100. The cover 68 is attached as in the first embodiment.

(Action)
Also in the drainage pipe structure 10 of the present embodiment, when a large amount of drainage is flowed to the sink 22 at one time as in the first embodiment, the drainage is discharged in volume as in the first embodiment. Since it first flows into the large drainage port member 28, it is possible to prevent the drainage from overflowing from the drainage port member 28.

Further, according to the drainage pipe structure 10 of the present embodiment, the pressure increase when the drainage is discharged from the dishwasher 26 can be alleviated by the pressure relaxation device 64 provided in front of the confluence pipe 80. The pressure increase acting on the S-shaped trap 40 can be further alleviated as compared with the first embodiment.

[Third Embodiment]
The drainage pipe structure 10 according to the third embodiment of the present invention will be described with reference to FIG. The same components as those in the first embodiment are designated by the same reference numerals, and the description thereof will be omitted.
In the drainage pipe structure 10 of the present embodiment, the merge pipe 80 is arranged on the downstream side in the drainage direction as compared with the case of the first embodiment, and is provided in the vicinity of the dishwasher 26.

As a result, the pipe length from the merging pipe 80 to the S-shaped trap 40 becomes relatively longer than the pipe length from the dishwasher 26 to the merging pipe 80, and the inside of the pipe from the merging pipe 80 to the S-shaped trap 40 The volume of the can be easily expanded.

Also in the drainage pipe structure 10 of the present embodiment, when the drainage is discharged from the dishwasher 26, the pressure inside the pipe on the downstream side in the drainage direction of the S-shaped trap 40 becomes positive, but as compared with the first embodiment. Therefore, since the volume in the pipe from the dishwasher 26 to the merging pipe 80 is relatively small and the volume in the pipe from the merging pipe 80 to the S-shaped trap 40 is relatively large, the pressure acting on the S-shaped trap 40 is applied. It can be more relaxed.

[Fourth Embodiment]
The drainage pipe structure 10 according to the fourth embodiment of the present invention will be described with reference to FIG. The same components as those in the first embodiment are designated by the same reference numerals, and the description thereof will be omitted.
As shown in FIG. 10, in the drainage port member 28 of the present embodiment, an eaves-shaped rib 104 that protrudes horizontally toward the inside of the cylindrical portion 28Aa is integrally formed on the inner peripheral portion of the cylindrical portion 28Aa. Has been done. The rib 104 is arranged above the opening (opening in the lateral direction) of the protrusion 28Ab on the inner peripheral surface of the cylindrical portion 28Aa. The protruding length of the rib 104 is not particularly specified, but it is preferable that the rib 104 protrudes from the inner surface of the cylindrical portion 28Aa by about 5 to 25 mm. In addition, the rib means a protruding one, and can be paraphrased as a protrusion or a convex portion.

In the drainage port member 28 of the present embodiment, even when a large amount of drainage is flowed to the sink 22, the drainage W flowing down along the inner surface of the cylindrical portion 28Aa of the drainage port member 28 is the protrusion 28Ab. The drainage W flowing down can be dispersed by the rib 104 in the left-right direction and in the direction away from the opening so as not to block the lateral opening. In other words, on the front side of the lateral opening, the drainage W flowing down along the inner surface of the cylindrical portion 28Aa does not interfere with the drainage Wa on the bottom 28B that is about to flow toward the opening. The rib 104 changes the direction of the flow of the drainage W flowing down. As a result, the drainage Wa of the bottom 28B of the drainage port member 28 can be smoothly flowed into the protruding portion 28Ab and discharged from the outlet 28C to the outside of the drainage port member 28.

[Fifth Embodiment]
The drainage pipe structure 10 according to the fifth embodiment of the present invention will be described with reference to FIGS. 11 and 12. The same components as those in the first embodiment are designated by the same reference numerals, and the description thereof will be omitted.
As shown in FIGS. 11A and 11B, in the drainage port member 28 of the drainage pipe structure 10 of the present embodiment, the entire lower portion of the cylindrical portion 28Aa is formed to have a diameter larger than that of the flange 28E. As shown in FIG. 11B, the tubular portion 28A has a circular shape in a plan view.

Since the outer diameter of the male screw 32 formed on the outer peripheral surface of the neck portion 28D is smaller than that of the flange 28E and the tubular portion 28A, the annular shape used in the first embodiment after forming the drainage port member 28. The nut 34 cannot be screwed into the male screw 32.

Therefore, when the drainage port member 28 of the present embodiment is attached to the sink 22, the split nut 106 that can be divided into two as shown in FIG. 12 is used. The split nut 106 is composed of a first half-split piece 106A formed in a semicircular shape and a second half-split piece 106B. Screw holes 108 are formed at both ends of the first half-split piece 106A, and holes 112 through which bolts 110 screwed into the screw holes 108 are inserted are formed at both ends of the second half-split piece 106B. ing.

In order to attach the split nut 106 to the male screw 32 of the drain port member 28, the first half split piece 106A and the second half split piece 106B face each other with the male screw 32 interposed therebetween, and the bolt 110 is inserted into the hole 112. Then, the split nut 106 can be attached to the male screw 32 by screwing it into the screw hole 108.

Since the drainage port member 28 of the present embodiment has an enlarged diameter of substantially the entire cylinder portion 28A, the volume of the drainage port member 28 of the first embodiment can be made larger than that of the drainage port member 28 of the first embodiment when compared at the same height. You can.

[Sixth Embodiment]
The drainage pipe structure 10 according to the sixth embodiment of the present invention will be described with reference to FIGS. 13 (A) and 13 (B). The same components as those in the first embodiment are designated by the same reference numerals, and the description thereof will be omitted.

In the drainage pipe structure 10 of the present embodiment, instead of the T-shaped confluence pipe 80 of the first embodiment, a substantially Y-shaped confluence pipe 114 shown in FIGS. 13A and 13B is used. Has been done.

The combined pipe 114 has a linear straight portion 114A arranged in the horizontal direction. One end side of the curved curved portion 114B is integrally connected to the side portion of the straight portion 114A so as to face the downstream side of the straight portion 114A at a relatively small angle with respect to the straight portion 114A.

In the merging pipe 114 of the present embodiment, the drainage from the dishwasher 26 flows into the curved portion 114B through the pipe 88, but the drainage discharged from the curved portion 114B to the straight portion 114A is relative to the straight portion 114A. Since the drainage is discharged from the dishwasher 26 toward the downstream side in the drainage direction at a relatively small angle, the pressure in the pipe on the S-shaped trap 40 side of the merging pipe 114 when the drainage is discharged from the dishwasher 26 suddenly increases. The rise is suppressed. The pressure on the S-shaped trap 40 side of the merging pipe 114 decreases depending on the flow velocity of the drainage discharged from the curved portion 114B to the straight portion 114A.

As a result, it is possible to prevent the S-shaped trap 40 from being broken when the drainage is discharged from the dishwasher 26.

[Other embodiments]
Although an example of the embodiment of the present invention has been described above, the embodiment of the present invention is not limited to the above, and can be variously modified and implemented without departing from the gist thereof. Of course there is.

In the above embodiment, the S-shaped trap 40 is provided on the downstream side in the drainage direction of the drainage port member 28, but other types of traps having a structure other than the S-shaped trap 40 are provided on the downstream side in the drainage direction of the drainage port member 28. It may have been drained.

In the drainage pipe structure 10 of the present embodiment, a siphon drainage system provided with a siphon drainage pipe 90 has been used, but it can also be applied to a conventional general drainage system that is not a siphon drainage system.

In the drainage port member 28 of the above embodiment, the illustration of a dust receiver (mesh or the like) for preventing foreign matter (for example, dust in the drainage) from being discharged to the downstream side is omitted, but the drainage port member 28 does not. Of course, a dust catcher may be provided. The dust receiver may be attached to the inflow port, or may be attached to the inside of the protrusion 28Ab, the outflow port 28C, or the like.

試験の結果、Ｓ字トラップから合流配管までの流路の容積Ａと、食洗機の排水トラップから合流配管までの容積Ｂとの比率Ａ／Ｂを１．０以上とすることで、食洗機から排水が排出された際のＳ字トラップの破封を抑制できることが分かる。 (Test example)
In order to confirm the effect of the present invention, a drainage pipe structure according to an example to which the present invention was applied and a drainage pipe structure according to a comparative example were prototyped, and whether or not the trap was broken was investigated.
The drainage pipe structure used in the experiment is the drainage pipe structure of the first embodiment shown in FIG. 1, in which the volume A of the flow path from the S-shaped trap to the merging pipe and the drainage trap of the dishwasher to the merging pipe. The ratio A / B to the volume B is variously changed. When changing the ratio A / B, the position of the combined pipe was changed without changing the size of the pipe. For example, in Example 2, the position of the merging pipe is closer to the dishwasher than in Example 1, and in Example 3, the position of the merging pipe is closer to the dishwasher.
In the test, whether or not the S-shaped trap was broken when the drainage was discharged from the dishwasher, and the value of the pressure increased in the flow path between the S-shaped trap and the merging pipe (based on atmospheric pressure). ) Was examined.

As a result of the test, by setting the ratio A / B of the volume A of the flow path from the S-shaped trap to the merging pipe to the volume B from the drain trap of the dishwasher to the merging pipe to 1.0 or more, the dishwasher was washed. It can be seen that the S-shaped trap can be prevented from breaking when the wastewater is discharged from the machine.

10 ... Drainage piping structure, 22 ... Sink (first water supply device), 26 ... Dishwasher (second water supply device), 28A ... Cylinder (drainage port body), 28 ... Drainage port member, 29 ... Inflow port, 40 ... S-shaped trap (first drain trap), 80 ... merging pipe (merging member), 82 ... drain trap (second drain trap), 114 ... merging pipe (merging member)

Claims (5)

Along with the axial direction facing up and down, the cylindrical portion having an inflow port at the upper part and the lower side portion of the cylindrical portion projecting toward at least one side in the radial direction of the cylindrical portion and toward the one side. The width is narrowed, and the tip side of the one side is provided with a drainage port main body having a protruding portion having an outlet connected to the trap, and a bottom portion that closes the cylindrical portion and the lower portion of the protruding portion .
The protrusion has a horizontal cross-sectional area larger than the opening area of the inlet.
Drainage port member. The entire lower portion of the cylindrical portion of the protruding portion has a diameter larger than that of the opening portion of the inflow port.
The drainage port member according to claim 1. The first water supply device to which the drainage port member according to claim 1 or 2 is attached, and
The first drain trap provided on the downstream side in the drain direction of the first water supply device,
A second water-related device provided separately from the first water-related device,
A second drain trap provided on the downstream side in the drain direction of the second water supply device, and
A merging member that joins the downstream side of the first drain trap in the drainage direction and the downstream side of the second drain trap in the drainage direction.
Equipped with
A drainage pipe structure in which the pipe volume from the merging member to the first drain trap is set in a range equal to or larger than the pipe volume from the merging member to the second drain trap. The drainage pipe structure according to claim 3 , wherein the pipe length from the merging member to the first drain trap is set longer than the pipe length from the merging member to the second drain trap. The merging member has a linear straight portion arranged horizontally on the downstream side in the drainage direction of the first drain trap.
A confluence pipe on the downstream side in the drainage direction of the second drain trap is integrally connected to the side portion of the straight portion toward the downstream side of the straight portion and is connected to the straight portion at an acute angle in a plan view. ing,
The drainage pipe structure according to claim 3 or 4.

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