JP3184863B2 - Pipe joint structure with hydraulic test function and its packing - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pipe joint structure having a water pressure test function in a main water pipe and the like and a packing thereof.

[0002]

2. Description of the Related Art For example, as shown in FIG. 11, a joint portion of a mortar lining tube A in which a mortar lining layer 2 is formed on the inner surface of an iron tube 1 is inserted into a receiving port 3 of one of the tubes A. The opening 4 is inserted, and a packing G is interposed all around between the inner surface of the receiving port 3 and the outer surface of the inserting port 4.
The pressing ring 5 fitted on the outer surface of the packing ring G is tightened to the flange 6 of the receiving port 3 with a bolt and nut 7 with a predetermined torque, and the end face of the packing G is pressed by the leading edge of the pressing ring 5 by the tightening. Is pressed between the inner surface of the receiving port 3 and the outer surface of the insertion port 4. When the packing G is inserted into the insertion opening 4, a lubricant is applied to the outer peripheral surface of the insertion opening 4 and the inner peripheral surface of the packing G.

[0003] In this pipe joint structure, a water pressure resistance test is required to prevent water leakage after the facility. The conventional testing means applies a predetermined water pressure to a space S formed inside the packing G between the inner surface of the receiving port 3 and the outer surface of the insertion port 4 to measure the leakage of the packing G. There is a technique described in Japanese Patent Publication No. 60-15155.

According to this description technology, as shown in FIGS. 11 and 12, annular sealing members 50 and 51 made of a water-resistant elastic material and having a substantially L-shaped cross section are connected from the distal end surface of the insertion opening 4 in the opening of the space S to the end. The inner peripheral surface and the rear end surface 52 of the receptacle 3 are respectively abutted and covered along the inner peripheral surface of the pipe having a normal diameter deeper than the inner peripheral surface. The flange portion 51a contacting the portion 50a and the receiving end end step surface 52 is formed of a rubber magnet,
It can be magnetically attached to the iron pipe portions of the insertion port 4 and the receiving port 3. A plurality of wires 53 such as piano wires are provided on the inner wall portion 50b contacting the inner peripheral surfaces of the insertion openings of the seal members 50 and 51 and the inner wall portion 51b contacting the inner peripheral surface of the receiving opening.
54 are inserted in the circumferential direction, and adhere to the inner peripheral surfaces of the insertion opening 4 and the receiving opening 3 by its own elasticity.

The two annular sealing members 50, 51
Is a rubber annular seal band 5 in which a lip 57 portion abuts against the inner wall portions 50b and 51b to form a sealed space 56.
5 is pressed by the pressing device 59. The pressing device 59 comprises a bolt 60 screwed to the annular frame 58 so as to be able to advance and retreat in the radial direction, and a plurality of annular pressing plates 61 circumferentially fitted in the seal band 55. Is rotatably connected to the inner periphery of the pressing plate 61, and the pressing plate 61 is provided so as to expand its diameter and press the seal band 55 by the rotation of the bolt 60. Reference numeral 62 denotes a guide holding member that regulates the rotation of the pressing plate 61 and guides the diameter expanding operation.

In the prior art of this construction, after the space S and the sealed space 56 are made water-tight by the pressing device 59 via the sealing members 50 and 51 and the seal band 55, as shown in FIG. Water is sent into the space S and the sealed space 56 by a pump 71 through a hose 74, and a predetermined pressure is applied to inspect the water leakage. In the figure, 7
2 is an opening / closing valve and 73 is a water pressure meter.

[0007]

The above prior art has the following problems.

The pipe A is provided with a mortar lining layer 2 and the like on the inner surface of the iron pipe 1 to form an anticorrosion layer. However, since a high water pressure is applied to the packing G via the space S and the sealed space 56, the sealing member 50 is used. , 51 flange portions 50a, 5
If the magnetic coating 1a is inadequate in its magnetic deposition, it may float from this location, and high-pressure water may enter between the mortar lining layer 2 and this layer 2 and the iron pipe 1, and the anticorrosion layer is broken by the flooding. And the anticorrosion effect may be impaired. To eliminate these fears, the sealing members 50, 51
Must be surely pressed, which leads to a reduction in workability.

In a state where the pipe A is not buried, when high water pressure is applied to the space S formed by the receiving port 3, the receiving port 4 and the packing G, the receiving port end is separated from the receiving port rear end to maintain a predetermined distance. Or the joint (joint) is detached. For this reason, in such a conventional water pressure test, after the pipe is buried in the ground, the joint is placed in a fixed state, and the water pressure test must be carried out by bringing the water pressure test device into the pipe A as shown in FIG. No. At this time, since the device is buried, the carry-in distance of the device is inevitably increased. Also, as a result of the water pressure test, if there is a water leakage point, the joint of the pipeline must be dug up and repaired, which causes excessive economic loss. This is especially true if there are many leaks at each joint.

If the installation of the hydraulic test devices such as the seal members 50 and 51 and the seal band 55 is incomplete,
There is a case where a predetermined water pressure test cannot be performed due to the above-mentioned water infiltration or water leakage from the pressure contact portion between the seal members 50 and 51 and the seal band 55.

[0011] The number of parts of the hydraulic test equipment such as the pressing device 59 is also large, and they must be divided and carried into the pipe A from the shaft or the pipe end opening to assemble them. And require effort.

When the diameter of the joint pipe A is small and a person cannot enter the pipe A, the above-mentioned conventional technique cannot be used. In this case, after the pipe A is buried as described above, , Both ends of the pipeline are closed with lids, filled with water in the pipeline and pressurized,
It is common to check for leakage at the junction. As a result of the water pressure test, if water is leaking, the excavation and repair must be performed after searching for a leaking point, so that an excessive economic loss is incurred.

The present invention solves the above-mentioned conventional problems, and eliminates the need for a hydraulic pressure test apparatus that needs to particularly protect the portion between the pipe and the lining layer at the end of the insertion port and the deep step of the receiving port. The task is to make the water pressure test possible.

[0014]

In order to solve the above problems, the present invention relates to a pipe joint structure in which a packing G is pressed between a receiving port 3 and an insertion port 4 by a press ring 5 shown in FIG. Grooves are formed on the inner and outer peripheral surfaces of the packing over its entire circumference, and both grooves are communicated with holes penetrating the packing, and any one of the receiving port, the insertion port, or the packing is provided with the groove. provided on at least one leading the water supply passage and the air discharge passage is, both opening to the groove of the discharge passage and its supply path Ru Nodea where the configuration on the other side around the tube axis.

With this configuration, when water is supplied from the water supply path, the water in the groove and the communication hole is discharged to the outside from the air discharge path, and after the discharge is completed, the air discharge path is closed. Apply the required water pressure in the groove. The water pressure is applied from the middle of the packing to the space between the packing and the inner surface of the receptacle and between the outer surface of the insertion port through the inner and outer grooves, and a watertight test of the packing portion is performed. At this time, since the water pressure does not act in a direction in which the receiving port and the insertion port are separated from each other, there is no fear that the receiving port and the insertion port are separated. For this reason, it is not necessary to perform the operation in a fixed state buried underground.

[0016]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS As a specific embodiment of the water supply passage and the air discharge passage, a hole penetrating from the outer surface of the receiving port to the inner surface is formed. that give adopted what was provided. In this way, water pressure can be applied from the outside of the tube, and after the test is completed, the supply / drainage path is closed with the stopper to bury the pipe.

As the packing used in this case,
Grooves are formed over the entire circumference on the inner and outer peripheral surfaces of the packing, and both grooves are communicated with holes penetrating the packing, and ridges are formed on both sides of both grooves over the entire circumference. not good when you adopt a configuration that is. According to this packing, the ridges on both sides of the groove are strongly pressed against the inner surface of the receiving port and the outer surface of the insertion port as compared with the other parts, in order to prevent the groove from collapsing as much as possible, the water smoothly reaches the entire circumference of the groove, Water pressure is applied evenly around the packing. Therefore, a highly accurate water pressure test can be performed.

As another specific embodiment of the water supply passage and the air discharge passage, a pipe formed integrally with the packing is provided. The pipe communicates with the groove through the inside from the outer surface of the packing, Passing between the inner surface of the receiving port and the outer surface of the insertion port, it is guided to the inner surface or the outer surface of the pipe, and a groove is formed on the inner surface of the receiving port or the outer surface of the insertion port to fit the pipe and lead to the inner surface or the outer surface of the tube. is, the out end of the inner surface or the outer surface of the pipe that give adopted what closure plug is provided. With this configuration, it is possible to apply water pressure without making a hole on the pipe (reception port and insertion port) side.

In this case, when the pipe is led to the outer surface of the pipe, the opening of the groove for fitting the pipe is
A shape having a circumference of more than cross-section half, have good when so screwed the closure plug in the opening. In this way, a closure plug can be attached to the receptacle or insertion port,
The mounting state is stabilized (certain).

[0020] packing grayed with the pipe, the pipe is formed by bulging the packing outer surface, not good if it is assumed that he Shirubebi to pressure end face side of the press wheel. By doing so, the pipe can be settled well and packing can be performed with good workability.

[0021]

FIG. 1 to FIG. 4 show an embodiment. The packing G1 of this embodiment is made of the same pressure-resistant rubber as that of the prior art, and has a pressing ring contact portion 20 at one end and a tapered portion at the outer periphery. 1
1 and an outer peripheral round portion (projecting ridge) 12 projecting in an annular shape, and an outer peripheral round portion (projecting ridge) 14 is formed on the other end portion. Protruding inner peripheral round portions (protrusions) 16 and 15 are provided. This round part 1
2 and the round portion 16 and the other round portion 14 and the round portion 15 are shown in FIG.
As shown, they form the same outer peripheral surface with the same center
(Forming part of the same circle). Outer round part 12, 14
Between the inner circular section 16 and the inner circular section 15, an annular and concave outer peripheral water path (groove) 18 and an inner peripheral water path (groove) 1 in the circumferential direction are respectively provided.
7, a water channel (hole) 1 penetrating between the water channels 18, 17
3 are provided at a plurality of locations in the circumferential direction (at equal intervals).

This packing G1 is interposed in the pipe joint shown in FIG.
A receiving channel 25 penetrating from the outer surface toward the outer peripheral channel 18 of the packing G1 is provided at a vertically symmetric position of the receiving port 3. An annular packing 38 is provided on the outer surface side of the receiving channel 25.
The stopper 37 is screwed into the water to stop the water, and usually prevents intrusion of earth and sand or water from the outside. The stopper 37 has a hexagonal recess for turning the head, and is attachable and detachable with a handle (not shown) (see FIG. 4).

In the interposed state of the packing G1,
The inner and outer water passages 17, 18 and the water passage 13 are secured as water passages even when the packing G1 is compression-fitted as shown in FIG. In this state, both plugs 37 are removed, and an open / close valve (see reference numeral 39 in FIG. 5) is connected to the upper receiving water channel 25, and a hose 74 of a water supply device shown in FIG. 11 is connected to the lower water channel 25. I do. Thereafter, the valve of the upper receiving channel 25 is opened, and the water channels 17, 18 are filled with water from the lower receiving channel 25 by the hydraulic pump 71, and the valve is closed when the air in each of the channels has been removed.

With this water supply, the watertightness between the receiving port 3 and the inserting port 4 at the joint portion by the packing G1 which is compression-fitted into the space between the outer peripheral surface of the receiving port 4 and the inner peripheral surface of the receiving port 3 is improved. Can be easily tested. That is, the test can be performed using the inserted state of the packing, which is one of the pipe joining procedures. In this water pressure test, the water pressure pump 71 is driven to increase the pressure to a specified water pressure.

When pressurized by the hydraulic pump 71, the water pressure is equally distributed on the inner peripheral surface of the receiving port 3 in contact with the inner and outer water paths 17 and 18, the outer peripheral surface of the insertion port 4 and the round parts 12, 14 and 16, 15 direction. Since it is applied, no force is exerted by the water pressure in the direction of pulling out the joint. If there is no abnormality in the hydraulic pressure test, disconnect the hose connection between the valve of the upper receiving channel 25 and the lower receiving channel 35. Thereby, the water in the water channels 17, 18, and 13 is discharged from the lower receiving water channel 25. At this time, the compressed air can be introduced into the water channel 17 and the like via the water channel 25 to reliably discharge the water.
Thereafter, when the stopper 37 is attached to the upper and lower receiving channels 25, the hydraulic pressure test is completed. Then, the pipe A is buried.

FIGS. 5 to 7 show another embodiment, which is different from the above embodiment in that a pipe for an air discharge passage and a water supply passage is provided in the packing G, and the pipe is fitted to the inner surface of the receiving port 3. The difference is that a mating groove is formed. Therefore, the water channel 25 of the receiving port 3 is eliminated.

That is, the packing G2 of this embodiment
Is provided with a pair of straight ridges 30 each having a semicircle or more in cross section in the taper direction of the outer peripheral tapered portion 11 of the packing G1 of the above embodiment, symmetrically in the circumferential direction. The projecting ridge 30 bulging from the tapered portion 11 has a hollow center so as to form a water channel 13a. The water channel 13a extends into the packing G2 from before the round portion 12 to reach the water channel 13. That is, the pipe is formed by the ridge 30 and the water channel 13a. The protruding ridge 30 has disappeared before the pressing wheel contact portion 20, and an arc surface 37 a corresponding to the outer diameter of the plug 37 is formed on the outer peripheral surface 11 in front of the disappearing step portion 30 a.

The ridge 3 of the packing G2 on the inner peripheral surface of the socket 3
An arc-shaped fitting groove (fitting groove) 32 having a cross-sectional shape of the ridge 30 is formed inward from the base of the flange 6 toward the inside at a position opposed to 0. Flange 6 of this groove 32
A thread groove (female thread) 37b of the plug 37 is formed at the side opening end. At this time, as shown in FIGS. 7B and 7D,
Since the ridges 30 (grooves 32) have the same cross-sectional shape and a half or more circumference, the plug 37 can be screwed into the threaded portion 37b of the groove 32 without coming off. The opening width of the groove 32 is set to
Although it is set slightly smaller than the cross-sectional outer diameter of 0, the ridges 30 can be elastically deformed and fitted into the grooves 32. After insertion,
This fitting does not close the water channel 13a. The through-hole 34 of the hose 74 is formed in the pressing wheel 5.

The stopper 37 is provided with a water stop rod 37c.
The watertightness is secured by fitting the 7c into the water channel 13a. The packing 38 described above may be employed instead of the water stop rod 37c, or both of them 37c and 38 may be used in combination.

The water pressure test of this embodiment was performed in the same manner as described above.
The stopper 37 is removed, the open / close valve 39 is connected to the upper water passage 13a (pipe), and the water supply device is connected to the lower water passage 13a (pipe). After this, the waterways 13, 17, 18, 13
The air in a is removed, the valve 39 is closed, and a water pressure test is performed.

FIGS. 8 to 10 show still another embodiment, which is different from the above-mentioned embodiment in that a pipe is connected to the receiving port 3 and the space S between the receiving port 4.
The point that led to the side is different. That is, the pipe 40 is formed by integral molding from the front surface of the packing G3, the inside of the pipe 40 is used as the water channel 13a, and the plug 37 is inserted into the opening.
The threaded groove (female thread) 40a is formed. The female thread 40a may be formed directly on the pipe 40, or another thread such as a nut may be fitted and fixed. The stopper 37 is the water stop rod 3
7c may or may not be provided, and the packing 38 can be freely interposed. It is advisable to appropriately insert a full length or a part of a reinforcing pipe into the water channel 13a. The reinforcing tube is preferably inserted by inner molding, and may employ various materials such as steel and plastic.

A groove 42 into which the pipe 40 is fitted is formed in the inner surface of the receiving port 3.
The cross-sectional diameter of the groove 42 is set slightly smaller than the cross-sectional diameter of the pipe 40, and the water channel 13a does not close.

Incidentally, in order to make the joining state shown in FIG. 8, the pressing ring 5 is deposited (fitted) around the outer periphery of the insertion port 4 as in the conventional case.
The packing G3 is deposited on the inner peripheral surface of the receiving port 3 in a state where the pipe 40 of the packing is fitted in the groove 42, and the insertion port 4 is inserted.
Apply lubricant to the outer peripheral surface of the packing and the inner peripheral surface of the packing.
Is pressed into the packing G3 deposited in the receptacle 3, the end of the push wheel 5 is brought into contact with the push wheel contact portion 20, and the bolt and nut 7 are tightened to the specified torque.

This embodiment can be adopted in the case where the diameter of the pipe A is large and a person can enter the pipe A. The water pressure test is performed by removing the stopper 37 and the upper water passage 13 as described above.
The open / close valve 39 is connected to a, and a water supply device is connected to the lower water passage 13a. After this, the waterways 13, 17, 18, 13
The air in a is removed, the valve 39 is closed, and a water pressure test is performed.

In the embodiment shown in FIG. 5, the water passage 13a may penetrate the inside of the packing G2 as shown by a chain line in the figure, but in this case, it is necessary that the water passage 13a is not closed by pressure contact. Alternatively, a pipe having one end connected to the packing G2 as in the embodiment of FIG. The grooves 32 and 42 may be formed on the insertion port 4 side. At this time, the ridge 30 and the pipe 40 are also on the insertion port side. The cross-sectional shape of the ridge 30 and the pipe 40 is not limited to a round shape, but may be any shape such as a triangle and a square. At this time, it is preferable that the groove 32, 42 be shaped so as to cover the entire cross section.

[0036]

The present invention is configured as described above, and is provided with a water pressure test function added to the packing.
The water filling pressure does not act in the direction of separation between the insertion port and the receiving port, the two are not separated by the test, and the water pressure test is performed on the joint immediately after pipe joining in normal piping work and in a non-buried state. be able to. Being able to perform the test in a non-buried state means that even if the joints are defective in the hydraulic test, it is possible to perform the joining again on the spot, as in the prior art Since re-excavation is not required, the number of work steps and costs can be reduced.

Further, since a water pressure is directly applied to the packing and the entire circumference of the gap between the insertion port and the receiving port is not closed to perform a water pressure test, a test apparatus having a means for closing the gap can be separately carried in. The test can be performed simply by connecting a hydraulic pump to the packing water channel (groove) without the need for assembly, and the workability is good. Water does not penetrate into the back surface at all, and there is no loss of the lining layer or impaired anticorrosion performance. In addition, the water supply tank may be small, since the amount of water to be charged may be small.

As long as the pipe is filled from the outside of the pipe, it is not necessary to conduct a water pressure test after closing the pipe end and filling the water, even in a small-diameter pipe. Can be.

[Brief description of the drawings]

FIG. 1 is an enlarged sectional view of a main part of an embodiment of a pipe joint structure according to the present invention.

FIG. 2 is a perspective view of the packing of the embodiment.

FIG. 3 is a cutaway front view of the upper half of the packing.

FIG. 4 is an enlarged view of a main part of FIG. 1;

FIG. 5 is an enlarged view of a main part of another embodiment.

FIG. 6 is an upper half cutaway front view of the packing of the embodiment.

FIG. 7A is an enlarged sectional front view of a main part of the embodiment,
(B) is a cutaway left side view of (a), (c) is a cutaway front view of only the socket portion of (a), and (d) is a left side view of only the packing portion of (a).

FIG. 8 is an enlarged view of a main part of another embodiment.

FIG. 9 is a cutaway front view of the upper half of the packing of the embodiment.

10A is a cross-sectional view taken along line XX of FIG. 8, and FIG. 10B is an enlarged cross-sectional view of a main part of the packing.

FIG. 11 is a sectional view of a conventional example.

FIG. 12 is an enlarged view of a main part of the conventional example.

[Explanation of symbols]

 A Joint pipe G, G1, G2, G3 Packing 1 Iron pipe 2 Mortar lining layer 3 Receptacle 4 Insertion port 5 Press ring 6 Flange 7 Bolt nut 12, 14, 15, 16 Round part (projecting ridge) 13 Channel (communicating hole) 13a Water channel 17, 18 Water channel (groove) 25 Reception-side water channel 30 Ridge (pipe) 32, 42 Reception-side insertion groove 37 Plug 39 Air release opening / closing valve 40 Pipe 71 Water pressure pump

Continuation of the front page (56) References JP-A 2-74688 (JP, U) JP-A 60-98034 (JP, U) JP-A 61-206839 (JP, U) (58) Fields surveyed (Int .Cl. ⁷ , DB name) G01M 3/04

Claims (7)

(57) [Claims] [Claim 1] A receptacle 3 of one of the tubes A Insert the insert opening 4 of the other tube A, a packing grayed G 2, G3 the entire periphery between the insert opening 4 the outer surface and its socket 3 inner surface interposed And the insertion slot 4
The pressing ring 5 fitted on the outer surface of the packing is tightened to the flange 6 of the receiving port 3 with a bolt and nut 7. By the tightening, the end face of the packing is pressed by the leading edge of the pressing ring 5 so that the packing is brought into contact with the inner surface of the receiving port. In the pipe joint structure pressed between the outer surfaces of the insertion holes, grooves 17, 1, 1, 1.
8 are respectively formed, the two grooves 17 and 18 are communicated with a hole 13 penetrating the packing, and the packing has a water supply passage 13 communicating with at least one of the grooves.
a and an air discharge path 13a are provided, and both openings of the supply path and the discharge path to the groove are located on opposite sides with respect to the pipe axis, and the water supply path and the air discharge path are connected to the packing. Without the integrally formed pipes 30, 40, this pipe is
The groove 1 passes through the inside from the outer surface of the packing G2, G3.
While communicating with 7, 18 and passing between the inner surface of the receiving port and the outer surface of the insertion port, it is led to the inner surface or outer surface of the pipe A,
Grooves 32 and 42 are formed on the inner surface or outer surface of the receiving opening to guide the pipe into the inner surface or outer surface of the pipe, and a closing plug 37 is provided at a leading end of the inner surface or outer surface of the pipe. A pipe joint structure with a water pressure test function. 2. When the pipe is led to the outer surface of the pipe, the opening of the groove 32 into which the pipe 30 is fitted is formed to have a shape having a circumference of at least half a cross section, and the closing plug 37 is inserted into the opening. Claims characterized by being screwed in
2. A pipe joint structure with a water pressure test function according to 1 . 3. The insertion port 4 of the other tube A is inserted into the receiving port 3 of one pipe A, and packings G1, G2, G3 are interposed all around the inner surface of the receiving port 3 and the outer surface of the receiving port 4. Then, the pressing ring 5 fitted to the outer surface of the insertion port 4 is tightened to the flange 6 of the receiving port 3 with a bolt and nut 7, and by the tightening, the end face of the packing is pressed by the leading edge of the pressing ring 5. The packing is pressed against the inner surface of the receptacle and the outer surface of the insertion hole, and the inner and outer peripheral surfaces of the packing have grooves 17, 1, 1.
8 are formed, and both grooves 17 and 18 thereof are communicated with each other by a hole 13 penetrating the packing.
Either the insertion opening 4 or the packing is provided with a water supply path 25, 13a and an air discharge path 25, 13a communicating with at least one of the grooves. Both openings of the supply path and the discharge path to the groove are provided. a said packing G1, G2, G3 of using the tube axis <br/> hydrostatic testing function fitting structure is positioned on the opposite side of the center, over its entire circumference on the inner peripheral surface of the packing of that Grooves 17, 1
8 are formed, the two grooves 17 and 18 are communicated with the hole 13 penetrating the packing, and
On both sides of 7, 18 the ridges 12, 14, 1
5 and 16 are formed, and the hole 13 is
Packing characterized by being provided at a plurality of places at equal intervals in the king circumferential direction . 4. An insertion opening 4 of the other tube A is inserted into a receiving opening 3 of one tube A, and packings G1, G2, G3 are interposed between the inner surface of the receiving opening 3 and the outer surface of the insertion opening 4. Then, the pressing ring 5 fitted to the outer surface of the insertion port 4 is tightened to the flange 6 of the receiving port 3 with a bolt and nut 7, and by the tightening, the end face of the packing is pressed by the leading edge of the pressing ring 5. The packing is pressed against the inner surface of the receptacle and the outer surface of the insertion hole, and the inner and outer peripheral surfaces of the packing have grooves 17, 1, 1.
8 are formed, and both grooves 17 and 18 thereof are communicated with each other by a hole 13 penetrating the packing.
Either the insertion opening 4 or the packing is provided with a water supply path 25, 13a and an air discharge path 25, 13a communicating with at least one of the grooves. Both openings of the supply path and the discharge path to the groove are provided. The packings G1, G2, and G3 used in the pipe joint structure with a hydraulic test function, which are located on the opposite side with respect to the pipe axis, and the inner and outer peripheral surfaces of the packing have grooves all around the pipe. 17, 1
8 are formed, the two grooves 17 and 18 are communicated with the hole 13 penetrating the packing, and
On both sides of 7, 18 the ridges 12, 14, 1
5, 16 are formed, and the inner and outer peripheral surfaces of the packing on the same side
The ridges 12 and 16 and the ridges 14 and 15 of the
A packing characterized by forming a single-circle outer circumference of the same circle . 5. The packings G2 and G3 used for the pipe joint structure with a hydraulic test function according to claim 1 or 2 , wherein the inner and outer peripheral surfaces of the packing have grooves 17 and 1 extending over the entire circumference thereof.
8 are formed, and both grooves 17 and 18 are
Communicating with each other through a hole 13 penetrating the
On both sides of 7, 18 the ridges 12, 14, 1
5 and 16 are formed, and the pipes 3 forming the water supply path and the air discharge path
0 and 40 are formed by integral molding with the packing.
The packing passes from the outside of the packing to the inside through the packing
While communicating with the grooves on the inner and outer surfaces of the
Are fitted in the grooves 32 and 42 on the outer surface of the insertion port, and
A packing provided so as to be guided to a surface . 6. the pipe 30 is formed by bulging the packing G2 outer surface, packing according to claim 5, characterized in that that he Shirubebi the pressure contact edge side of the push ring 5. 7. A ridge 12, a ridge 16, a ridge 14, and a ridge 1 on the inner and outer peripheral surfaces of the packing on the same side of the grooves 17, 18.
The packing according to claim 3, 5 or 6, wherein each of the five (5) forms an outer peripheral surface of a single circle.