JP7019988B2 - Resin elbow fitting - Google Patents

Description

The present invention relates to a resin elbow joint .

In fluid supply systems such as water supply systems in buildings, multiple pipes for flowing fluid (water, etc.) are provided, and among these pipes, the pipes extending at approximately right angles should be connected by resin elbow joints. What was done is known.

As shown in Patent Document 1, the resin elbow joint has a resin joint body having an L-shaped corner portion integrally formed with respect to both the first straight portion and the second straight portion. I have. This joint body is formed by injection molding. The first straight portion of the joint body is provided with a first lock mechanism for preventing the first pipe connected to the first straight portion from coming off. Further, the second straight portion of the joint body is provided with a second lock mechanism for preventing the second pipe connected to the second straight portion from coming off.

FIG. 6 shows a mold 92 for forming a joint body 91 of a resin elbow joint by injection molding. In the mold 92, a pair of pins 93, 94 extending linearly in a direction orthogonal to each other are arranged so that the tips thereof abut each other. Then, the molten resin is injected into the mold 92 to cure the resin around the pins 93 and 94, and then the pins 93 and 94 are pulled out so that the tips of the pins 93 and 94 are separated from each other at the same time as the mold is opened to form the joint body 91. Will be done.

Design Registration No. 1474055 Gazette

In the resin elbow joint, when the joint body 91 is formed by the injection molding described above, it is necessary to pull out the pins 93 and 94 as the mold opens. Therefore, the pins 93 and 94 must be formed linearly. The corner portion 95 (FIG. 6) of the joint body 91 formed by the pins 93 and 94 has a bent shape. Therefore, in the fluid supply system, the pressure loss due to the fluid passing through the corner portion 95 of the resin elbow joint (joint body 91) becomes large. When the piping of the fluid supply system is provided so as to avoid the structure of the building due to the remodeling of the building, there are many portions where the piping bends, that is, a portion where a resin elbow joint is provided. As the number of resin elbow joints used in the fluid supply system increases in this way, the fluid supply plug at the end of the fluid supply system accompanies the increase in pressure loss at the corner portion 95 described above in each resin elbow joint. The flow rate of the fluid is reduced.

An object of the present invention is to make it possible to keep the pressure loss caused by the fluid passing through the corner portion of the resin elbow joint to be small.

Hereinafter, means for solving the above problems and their actions and effects will be described.
The resin elbow joint that solves the above problems includes a resin joint body having an L-shaped corner portion that is integrally formed with the first straight portion and the second straight portion so as to be connected to each other. Further, the resin elbow joint has a first lock mechanism for preventing the first pipe connected to the first straight portion from coming off, and a second locking mechanism for preventing the second pipe connected to the second straight portion from coming off. It is equipped with a two-lock mechanism. Then, the inner peripheral surface of the corner portion in the joint body is formed by the insert.

According to the above configuration, when the joint body is formed by injection molding, the insert and the insert in the mold are arranged in a state where the inserts are arranged in the mold and the tips of a pair of pins are aligned with the ends of the inserts. Inject the molten resin around the pin. Then, after the resin is cured, the joint body is formed by pulling out the pin together with the mold opening, and the inner peripheral surface of the corner portion in the joint body is formed by the insert. By forming the joint body in this way, the inside of the corner portion can be smoothed as follows. That is, the apex portion, the inlet portion, and the inner peripheral surface of the exit portion of the insert forming the inner peripheral surface of the corner portion are each made into a perfect circle in advance, and the inner peripheral surface of the inlet portion and the inner peripheral surface of the apex portion are smooth. At the same time, the inner peripheral surface of the same apex and the inner peripheral surface of the exit portion are smoothly connected. Then, by forming the joint body as described above using the insert, the inside of the corner portion in the joint body can be smoothed. As a result, in the resin elbow joint, the pressure loss due to the fluid passing through the corner portion can be suppressed to a small value.

A method for manufacturing a resin elbow joint that solves the above problems is a resin joint body having an L-shaped corner portion integrally formed with the first straight portion and the second straight portion so as to connect the first straight portion and the second straight portion. A resin elbow including a first lock mechanism for preventing the first pipe connected to the first straight portion from coming off and a second lock mechanism for preventing the second pipe connected to the second straight portion from coming off. Applies to fittings. In this manufacturing method, the joint body of the resin elbow joint is formed by injection molding. Specifically, the joint body is formed by arranging an insert for forming the inner peripheral surface of the corner portion in the mold for performing such injection molding and injecting resin into the mold in that state. I am doing it.

According to the above method, the inside of the corner portion in the joint body can be smoothed as follows. That is, the apex portion, the inlet portion, and the inner peripheral surface of the exit portion of the insert forming the inner peripheral surface of the corner portion are each made into a perfect circle in advance, and the inner peripheral surface of the inlet portion and the inner peripheral surface of the apex portion are smooth. At the same time, the inner peripheral surface of the same apex and the inner peripheral surface of the exit portion are smoothly connected. Then, by forming the joint body as described above using the insert, the inside of the corner portion in the joint body can be smoothed. As a result, in the resin elbow joint, the pressure loss due to the fluid passing through the corner portion can be suppressed to a small value.

In the insert that solves the above problems, the inner peripheral surfaces of the apex, the entrance, and the exit are each in the shape of a perfect circle, and the inner peripheral surface of the entrance and the inner peripheral surface of the apex are smoothly connected and the apex is connected. The inner peripheral surface of the outlet and the inner peripheral surface of the exit portion are smoothly connected.

According to this configuration, by forming the inner peripheral surface of the corner portion in the joint body by the insert, the inside of the corner portion in the resin elbow joint becomes smooth. As a result, in the resin elbow joint, the pressure loss due to the fluid passing through the corner portion can be suppressed to a small value.

Sectional drawing which shows the resin elbow joint and the piping cover which covers it. Front view showing the piping cover. Sectional drawing which shows the resin elbow joint. Sectional drawing which shows the mold for forming the joint body of a resin elbow joint. FIG. 6 is a cross-sectional view showing another example of a resin elbow joint. FIG. 3 is a cross-sectional view showing a conventional example of a mold for forming a joint body of a resin elbow joint.

Hereinafter, a resin elbow joint, a method for manufacturing the resin elbow joint, and an embodiment of the insert will be described with reference to FIGS. 1 to 4.
The resin elbow joint 1 shown in FIG. 1 is provided to connect pipes extending at right angles among a plurality of pipes (pipes) for flowing water in a water supply system or the like of a building. The resin elbow joint 1 includes a resin joint body 5 having an L-shaped corner portion 4 integrally formed with respect to both the first straight portion 2 and the second straight portion 3. As the resin forming the joint body 5, for example, it is conceivable to use a mixture of polyphenylene sulfide resin and glass fiber.

In the joint body 5, the first straight portion 2 and the second straight portion 3 are formed in a cylindrical shape extending linearly in a direction perpendicular to each other, and the corner portion 4 is the first straight portion 2 and the second straight portion. It is formed in a cylindrical shape that curves in an arc shape so as to connect with 3. The first straight portion 2 is provided with a first lock mechanism 7 for preventing the pipe 6 (first pipe) connected to the first straight portion 2 from coming off. Further, the second straight portion 3 is provided with a second lock mechanism 9 for preventing the pipe 8 (second pipe) connected to the second straight portion 3 from coming off.

In the resin elbow joint 1, the equivalent pipe length is set to be less than 1.0 m, and more specifically, the equivalent pipe length is set to be less than 0.8 m. Here, the equivalent pipe length is a value representing a pressure loss when a fluid (water in this example) passes through the resin elbow joint 1, and becomes a smaller value as the pressure loss becomes smaller. This equivalent pipe length can be obtained by the following procedures (A) to (C).

(A) Measure the pressure difference between the upstream and downstream of the elbow joint when a constant flow rate of water is passed through the elbow joint.
(B) For a straight pipe having an inner diameter suitable for the elbow joint, the pipe friction loss per 1 m in the pipe when the same flow rate of water as the constant flow rate flowed through the elbow joint in (A) above is flowed. Calculate in advance.

(C) The pressure difference measured in (A) above is divided by the friction loss per 1 m of the pipe in (B) above, and the value obtained by this is taken as the equivalent pipe length of the elbow joint.
As shown in FIG. 2, the entire resin elbow joint 1 is covered by the pipe cover 10 when it is installed as a part of the water supply system of the building. As shown in FIG. 1, the piping cover 10 has a first cover portion 10a extending in the same direction as the first straight portion 2 of the joint main body 5 and covering the first straight portion 2 and the first lock mechanism 7, and a joint main body. A second cover portion 10b extending in the same direction as the second straight portion 3 of 5 and covering the second straight portion 3 and the second lock mechanism 9 is provided.

Further, the piping cover 10 includes a corner cover portion 10c that connects the first cover portion 10a and the second cover portion 10b. The corner cover portion 10c covers the corner portion 4 of the joint body 5 and is curved along the corner portion 4. Incidentally, the curvature of the corner portion 4 in the joint body 5 is smaller than the curvature of the corner cover portion 10c in the piping cover 10. As a result, a large portion of the space between the cover 10 and the joint body 5 in the piping cover 10 corresponding to the corner portion 4 of the joint body 5 can be taken, and that portion is used as a heat insulating space or the like. It will be advantageous in some cases.

Next, the structure of the resin elbow joint 1 will be described in detail.
As shown in FIG. 3, in the joint body 5 of the resin elbow joint 1, the boundary portion of the corner portion 4 with the first straight portion 2 is the inlet portion 4a. An accommodating portion 11 for accommodating the end portion of the pipe 6 on the upstream side of the pipe 6 and the pipe 8 is provided in a portion of the inner peripheral surface of the first straight portion 2 near the corner portion 4. A step portion 12 is formed between the inner peripheral surface of the accommodating portion 11 and the inner peripheral surface of the inlet portion 4a at the corner portion 4. Further, a cylindrical in-core 13 made of metal is inserted at the end of the pipe 6. The immersion of the incore 13 in the pipe 6 is suppressed by the flange 13a formed at the end of the incore 13. Then, until the in-core 13 inserted into the end of the pipe 6 abuts on the step portion 12, the end of the pipe 6 is from the end of the first straight portion 2 to the accommodating portion 11 in the first straight portion 2. It is inserted in the inner peripheral surface of.

On the inner peripheral surface of the first straight portion 2, a seal portion 14 having a diameter larger than that of the accommodating portion 11 is provided in a portion between the accommodating portion 11 and the end portion of the first straight portion 2. In the seal portion 14, the seal ring 15, the spacer 16, the seal ring 17, and the holding ring 18 are arranged in this order from the accommodating portion 11 side toward the end portion side of the first straight portion 2. Then, when the end portion of the pipe 6 is inserted into the accommodating portion 11 of the first straight portion 2, the pipe 6 penetrates the seal ring 15, the spacer 16, the seal ring 17, and the holding ring 18. At this time, the seal rings 15 and 17 in the seal portion 14 are in contact with the outer peripheral surface of the pipe 6, whereby the water flowing in the joint body 5 is brought into contact with the outer peripheral surface of the pipe 6 and the inner peripheral surface of the seal portion 14. Leakage from the resin elbow joint 1 to the outside is suppressed.

The first lock mechanism 7 includes a holding member 19 for holding the pipe 6 on the first straight portion 2, and a cap 20 for attaching the holding member 19 to the first straight portion 2. The holding member 19 is provided with an annular lock ring 23 located between the fitting ring 21 and the split ring 22. The holding member 19 is located adjacent to the holding ring 18 arranged in the seal portion 14 of the first straight portion 2.

Further, the cap 20 is formed in a cylindrical shape. By arranging the split ring 22 and the lock ring 23 inside the cap 20 and further fitting the fitting ring 21 inside the cap 20, the split ring 22 and the lock ring 23 are prevented from falling off from the inside of the cap 20. Will be done. Under such a state, the cap 20 and the holding member are engaged with the first straight portion 2 by engaging the open end of the cap 20 with the same end portion at a portion radially overlapping with the end portion of the first straight portion 2. The first lock mechanism 7 composed of 19 is easily assembled.

With the first lock mechanism 7 (holding member 19 and cap 20) attached to the first straight portion 2, the end of the pipe 6 penetrates the holding member 19 and the cap 20 and the end of the first straight portion 2. When inserted into the accommodating portion 11 from the portion, the lock ring 23 of the holding member 19 presses the outer peripheral surface of the pipe 6. This prevents the pipe 6 from coming out of the first straight portion 2.

On the other hand, in the joint body 5 of the resin elbow joint 1, the second straight portion 3 and the second lock mechanism 9 have substantially the same configurations as the first straight portion 2 and the first lock mechanism 7, respectively. Therefore, in the following description of the second straight portion 3 and the second lock mechanism 9, the same portions as the first straight portion 2 and the first lock mechanism 7 are referred to as the first straight portion 2 and the first lock mechanism 7. The same reference numerals will be given for explanation.

In the joint body 5, the boundary portion of the corner portion 4 with the second straight portion 3 is the outlet portion 4b. An accommodating portion 11 for accommodating the end portion of the pipe 8 on the downstream side of the pipe 6 and the pipe 8 is provided at a portion of the inner peripheral surface of the second straight portion 3 near the corner portion 4. A step portion 12 is formed between the inner peripheral surface of the accommodating portion 11 and the inner peripheral surface of the outlet portion 4b at the corner portion 4. Further, an in-core 13 is inserted at the end of the pipe 8. The immersion of the in-core 13 in the pipe 8 is suppressed by the flange 13a. Then, until the in-core 13 inserted into the end of the pipe 8 abuts on the step portion 12, the end of the pipe 8 is from the end of the second straight portion 3 to the accommodating portion 11 in the second straight portion 3. It is inserted in the inner peripheral surface of.

On the inner peripheral surface of the second straight portion 3, a seal portion 14 having a diameter larger than that of the accommodating portion 11 is provided in a portion between the accommodating portion 11 and the end portion of the second straight portion 3. In the seal portion 14, the seal ring 15, the spacer 16, the seal ring 17, and the holding ring 18 are arranged in this order from the accommodating portion 11 side toward the end side of the second straight portion 3. Then, when the end portion of the pipe 8 is inserted into the accommodating portion 11 of the second straight portion 3, the pipe 8 penetrates the seal ring 15, the spacer 16, the seal ring 17, and the holding ring 18. At this time, the seal rings 15 and 17 in the seal portion 14 are in contact with the outer peripheral surface of the pipe 8, so that the water flowing in the joint body 5 is brought into contact with the outer peripheral surface of the pipe 8 and the inner peripheral surface of the seal portion 14. Leakage from the resin elbow joint 1 to the outside is suppressed.

The second lock mechanism 9 includes a holding member 19 for holding the pipe 8 on the second straight portion 3, and a cap 20 for attaching the holding member 19 to the second straight portion 3. The holding member 19 is provided with an annular lock ring 23 located between the fitting ring 21 and the split ring 22. The holding member 19 is located adjacent to the holding ring 18 arranged in the seal portion 14 of the second straight portion 3.

Further, the cap 20 is formed in a cylindrical shape. By arranging the split ring 22 and the lock ring 23 inside the cap 20 and further fitting the fitting ring 21 inside the cap 20, the split ring 22 and the lock ring 23 are prevented from falling off from the inside of the cap 20. Will be done. Under such a state, by engaging the open end of the cap 20 with the same end portion at a portion radially overlapping with the end portion of the second straight portion 3, the cap 20 and the holding member are engaged with the second straight portion 3. The second lock mechanism 9 composed of 19 is easily assembled.

With the second lock mechanism 9 (holding member 19 and cap 20) attached to the second straight portion 3, the end of the pipe 8 penetrates the holding member 19 and the cap 20 to penetrate the end of the second straight portion 3. When inserted into the accommodating portion 11 from the portion, the lock ring 23 of the holding member 19 presses the outer peripheral surface of the pipe 8. This prevents the pipe 8 from coming out of the second straight portion 3.

Next, the corner portion 4 of the joint body 5 will be described in detail.
The inner peripheral surface of the corner portion 4 of the joint body 5 is formed by a tubular insert 34 made of polyphenylene sulfide resin or the like. Therefore, the inlet portion 4a of the corner portion 4 is located at the end of the insert 34 on the side of the first straight portion 2, and the outlet portion 4b of the corner portion 4 is located at the end of the insert 34 on the side of the second straight portion 3. is doing. The insert 34 is formed by injection molding, and the end portion on the inner peripheral surface of the insert 34 on the first straight portion 2 side and the end portion on the second straight portion 3 side are chamfered. Has been done.

An apex portion 4c is provided at an intermediate position between the inlet portion 4a and the outlet portion 4b in the insert 34 (corner portion 4). The inner peripheral surface of the entrance portion 4a, the exit portion 4b, and the apex portion 4c of the corner portion 4 is located on the inner peripheral surface of the insert 34. The inner peripheral surfaces of the inlet portion 4a, the outlet portion 4b, and the apex portion 4c of the insert 34 each have a perfect circular shape, and inside the corner portion 4, the inner peripheral surface of the inlet portion 4a and the inner peripheral surface of the apex portion 4c are formed. And are smoothly connected, and the inner peripheral surface of the apex portion 4c and the inner peripheral surface of the exit portion 4b are smoothly connected. Incidentally, the inner diameters of the inlet portion 4a and the outlet portion 4b are made larger than the inner diameter of the apex portion 4c. Therefore, the inner diameter of the insert 34 (corner portion 4) gradually increases from the apex portion 4c toward the inlet portion 4a, and gradually increases from the apex portion 4c toward the exit portion 4b. Due to the structure of the corner portion 4, the equivalent pipe length of the resin elbow joint 1 is set to be less than 1.0 m, more specifically less than 0.8 m.

Next, a method for manufacturing the resin elbow joint 1 will be described in more detail, and a method for forming the joint body 5 will be described.
FIG. 4 shows a mold 35 for forming the joint body 5 by injection molding. In the mold 35 that has been molded, the insert 34 for forming the inner peripheral surface of the corner portion 4 is arranged, and a pair of pins 36, 37 extending in directions orthogonal to each other are arranged. The tips of the pins 36 and 37 are inserted into the inside of the insert 34 from the end of the insert 34 and abutted against each other. Then, the step portion 36a formed on the outer peripheral surface of the tip end portion of the pin 36 is brought into contact with one end surface of the insert 34, that is, the end surface of the corner portion 4 on the inlet portion 4a side. Further, the step portion 37a formed on the outer peripheral surface of the tip end portion of the pin 37 is brought into contact with the other end surface of the insert 34, that is, the end surface of the corner portion 4 on the exit portion 4b side.

After that, the molten resin is injected into the cavity around the insert 34 and the pins 36, 37 in the mold 35, and the resin is solidified around the insert 34 and the pins 36, 37 to form the joint body 5. Specifically, the first straight portion 2 of the joint body 5 is formed around the pin 36, the corner portion 4 of the joint body 5 is formed around the insert 34 and the insert 34, and the second straight portion 3 of the joint body 5 is formed around the pin 37. Formed in. Then, the pins 36 and 37 are pulled out in a direction away from the end face of the insert 34 together with the mold opening of the mold 35.

According to the present embodiment described in detail above, the following effects can be obtained.
(1) Since the inner peripheral surface of the corner portion 4 in the joint main body 5 is formed by the insert 34, the joint main body 5 can be formed by the above-mentioned method. By forming the joint body 5 by this method, the inside of the corner portion 4 can be smoothed as follows. That is, the inner peripheral surfaces of the apex portion 4c, the inlet portion 4a, and the exit portion 4b of the insert 34 forming the inner peripheral surface of the corner portion 4 are formed into a perfect circle in advance, and the inner peripheral surface and the apex portion 4c of the inlet portion 4a are formed in advance. The inner peripheral surface of the apex portion 4c and the inner peripheral surface of the outlet portion 4b are smoothly connected to each other. Then, by forming the joint body 5 using the insert 34 as described above, the inside of the corner portion 4 in the joint body 5 can be smoothed. As a result, in the resin elbow joint 1, the pressure loss due to the fluid passing through the corner portion 4 can be suppressed to a small value, and the equivalent pipe length of the resin elbow joint 1 is less than 1.0 m, more specifically less than 0.8 m. It becomes a small value. Therefore, even if the number of resin elbow joints 1 increases in the water supply system, it is possible to suppress a decrease in the flow rate of water at the water tap at the end of the water supply system.

The above embodiment can be changed as follows, for example.
-Instead of providing the in-core 13 to be inserted into the ends of the pipes 6 and 8, as shown in FIG. 5, the first straight is inside the accommodating portion 11 and the sealing portion 14 in the first straight portion 2 and the second straight portion 3. An inner cylinder portion 38 formed integrally with the portion 2 or the second straight portion 3 may be provided, and the end portion of the pipe 6 or the end portion of the pipe 8 may be inserted into the outer peripheral surface of the inner cylinder portion 38. In this example, when the ends of the pipes 6 and 8 are inserted into the outer peripheral surface of the inner cylinder portion 38, the ends of the pipes 6 and 8 are in contact with the ends and together with the same end portion, in the inner part between the inner cylinder portion 38 and the accommodating portion 11. A ring-shaped insertion guide 39 is provided to guide the insertion of the end portion by being pushed in.

The first straight portion 2 and the second straight portion 3 of the joint body 5 extend at a right angle, that is, the inclination angle between the center lines of the first straight portion 2 and the second straight portion 3 is 90 °. However, such an inclination angle does not necessarily have to be 90 °. For example, the inclination angle between the center lines may be a value within a predetermined range including 90 ° and may be a value other than 90 °.

The inner diameters of the apex portion 4c, the inlet portion 4a, and the outlet portion 4b of the insert 34 (corner portion 4) in the joint body 5 may be appropriately changed. For example, the inner diameters of the apex portion 4c, the inlet portion 4a, and the outlet portion 4b may be equal.

-As the resin forming the joint body 5, a polyphenylene sulfide resin mixed with glass fiber is exemplified, but other resins may be used.
The strength of the insert 34 may be increased by forming ribs extending in the direction along the flow of water in the resin elbow joint 1 on the outer peripheral surface of the insert 34.

The strength of the insert 34 may be increased by forming ribs extending in the direction along the flow of water in the resin elbow joint 1 on the inner peripheral surface of the insert 34.
The insert 34 may be formed by bending a linear pipe material into an arc shape.

The insert 34 may be divided into two by a plane including the center line thereof. In this case, the insert 34 is easily formed.
-Although the insert 34 is formed of polyphenylene sulfide resin, it may be formed of other resins. It is also possible to form the insert 34 from metal instead of resin.

-The resin elbow joint 1 may be applied to a fluid supply system other than the water supply system, for example, a hot water supply system.

1 ... Resin elbow joint, 2 ... 1st straight part, 3 ... 2nd straight part, 4 ... Corner part, 4a ... Entrance part, 4b ... Exit part, 4c ... Top part, 5 ... Joint body, 6 ... Pipe, 7 ... 1st lock mechanism, 8 ... pipe, 9 ... 2nd lock mechanism, 10 ... piping cover, 10a ... 1st cover part, 10b ... 2nd cover part, 10c ... corner cover part, 11 ... accommodating part, 12 ... Stepped portion, 13 ... incore, 13a ... flange, 14 ... seal portion, 15 ... seal ring, 16 ... spacer, 17 ... seal ring, 18 ... holding ring, 19 ... holding member, 20 ... cap, 21 ... fitting ring, 22 ... split ring, 23 ... lock ring, 34 ... insert, 35 ... mold, 36 ... pin, 36a ... stepped part, 37 ... pin, 37a ... stepped part, 38 ... inner cylinder part, 39 ... insertion guide.

Claims (2)

A resin joint body having an L-shaped corner portion integrally formed with respect to both the first straight portion and the second straight portion,
A first lock mechanism for preventing the first pipe on the upstream side connected to the first straight portion from coming off.
A second lock mechanism for preventing the second pipe on the downstream side connected to the second straight portion from coming off,
Equipped with
The inner peripheral surface of the corner portion is formed by the insert.
The boundary portion of the insert with the first straight portion is an inlet portion.
An accommodating portion for accommodating the end portion of the first pipe is provided on the inner peripheral surface of the first straight portion near the insert.
Between the inner peripheral surface of the accommodating portion and the inner peripheral surface of the inlet portion of the insert, a step portion is formed in which the insertion position of the first pipe in the accommodating portion is defined by contact with the insert. A resin elbow joint characterized by being A resin joint body having an L-shaped corner portion integrally formed with respect to both the first straight portion and the second straight portion,
A first lock mechanism for preventing the first pipe on the upstream side connected to the first straight portion from coming off,
A second lock mechanism for preventing the second pipe on the downstream side connected to the second straight portion from coming off,
Equipped with
The inner peripheral surface of the corner portion is formed by the insert.
The boundary portion of the insert with the second straight portion is an outlet portion.
An accommodating portion for accommodating the end portion of the second pipe is provided on the inner peripheral surface of the second straight portion near the insert.
A step portion is formed between the inner peripheral surface of the accommodating portion and the inner peripheral surface of the outlet portion of the insert to define the insertion position of the second pipe in the accommodating portion by abutting against the insert. A resin elbow joint characterized by being

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