KR20140012605A - Pipeline renewal pipe - Google Patents

Abstract

Provided is a pipe regeneration pipe that can be smoothly inserted into an existing pipe line having a bent portion and can prevent damage at the time of insertion into the existing pipe line and increase in pressure loss during fluid transportation. The pipeline rehabilitation pipe 1 is formed by spirally winding the reinforcement core material 3 made of hard resin on the outer circumferential surface of the tube body 2 made of soft resin, and follows the bent portion 15 of the existing pipe line 10. It is flexible so that it may be inserted in the existing pipe line 10, while making it bend. And the pipe wall part 4 of the pipe main body 2 located between the reinforcement core materials 3 and 3 can be bent so that it may protrude in a pipe diameter outer direction at the time of bending, and the pipe wall part 4 of the bent state can be bent. The pipe wall portion 4 in the bent state is made to have the reinforcing core material 3 by making the maximum protruding dimension L3 in the pipe radially outward direction smaller than the protruding dimension L2 in the pipe radially outward direction of the reinforcing core material 3. It prohibits more protruding in a pipe diameter outer direction.

Description

Pipe rehabilitation pipe {PIPELINE RENEWAL PIPE}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pipeline regeneration pipe inserted into an existing pipeline such as an aged sewer pipe or a gas pipeline to rebuild an existing pipeline.

Conventionally, a method for regenerating an existing pipeline for fluid transportation, such as an aging sewer pipeline, is to insert a pipeline regeneration tube into an existing pipeline without changing the existing pipeline and to replace the internal space with a new fluid. The method of making it into space is known. Most existing pipelines are constructed by appropriately connecting a straight pipe and an elbow pipe, and a bent portion close to the right angle exists in the element element. For this reason, what has flexibility is generally used as the pipe rehabilitation pipe | tube inserted in the existing pipe | tube which has such a curved part.

As a pipe rehabilitation tube having this kind of flexibility, as disclosed in Patent Documents 1 and 2, for example, a structure having a structure in which a rigid reinforcing core material is spirally wound around the outer circumferential surface of the flexible tube body is known. Since the pipe rehabilitation pipe having such a structure has flexibility and complementarity, it can be inserted into the existing pipe while bending along the curved portion of the existing pipe. At the time of insertion into the existing pipeline, the reinforcing core material protruding outward from the outer peripheral surface of the tube main body is mainly in sliding contact with the inner peripheral surface of the existing pipeline, so that the tube body that is easy to wear contacts the inner peripheral surface of the existing pipeline. By suppressing it, damage to a pipe main body can be reduced.

Patent Document 1: Japanese Patent Application Laid-Open No. 10-78190 Patent Document 2: Japanese Patent Application Laid-Open No. 2006-83608

In the above-mentioned pipe rehabilitation pipe, when it is bent along the curved part of an existing pipe | tube, and inserted in an existing pipe | tube, the inner peripheral side of the curved part of a pipe main body will loosen, and the curved part outer peripheral side will be extended. At this time, if the loose portion protrudes inwardly in the diameter of the tube, a pleated protrusion is formed inside the tube body to hinder fluid transportation, and there is a problem that the pressure loss during fluid transportation increases.

On the other hand, when a loose part protrudes outward of a pipe diameter, a corrugated protrusion arises on the outer side of a pipe main body, and this protrusion (part of a soft and easy-to-wear pipe main body) contacts the inner peripheral surface of an existing pipe line, There was a problem that damage such as tearing, perforation, rupture and the like tended to occur.

Therefore, the present invention eliminates the above-described problems, and can be smoothly inserted into the existing pipe line having the bent portion along the bent portion, and does not cause an increase in pressure loss during fluid transportation. An object of the present invention is to provide a pipe rehabilitation pipe that can reliably prevent damage to the pipe main body at the time of insertion into the tube.

The pipe rehabilitation pipe 1 of the present invention has flexibility and is inserted into the existing pipe line 10 to rebuild the existing pipe line 10, and the hard resin is formed on the outer circumferential surface of the soft pipe body 2. The reinforcing core member 3 is wound in a spiral manner, and the pipe wall portion 4 positioned between the reinforcing core members 3 and 3 adjacent to each other in the tube axis direction in the tube main body 2 is a pipe regeneration tube. It can be bent so that it may protrude in a pipe diameter outer direction at the time of the bending of (1), and the largest protrusion dimension L3 of the pipe diameter outer direction of the pipe wall part 4 of a bent state is made of the said reinforcing core material 3 By making it smaller than the protruding dimension L2 of a pipe diameter outer direction, it is characterized by restrict | limiting that the pipe wall part 4 of the said bending state protrudes in the pipe diameter outer direction rather than the said reinforcing core material 3, It is characterized by the above-mentioned.

Specifically, the pipe wall portion 4 in the bent state has a pair of standing pieces 4a and 4a standing up in the pipe radially outward direction, and the inner surfaces of these standing pieces 4a and 4a come into contact with each other. The protruding dimension in the radial direction outside the tube in the state where the outer surfaces of the standing pieces 4a and 4a are in contact with the reinforcing core materials 3 and 3, respectively, is defined as the maximum protruding dimension L3. Moreover, the width dimension L1 of the pipe-axis direction in the pipe wall part 4 of the said pipe main body 2 is 2 times or less of the protrusion dimension L2 of the pipe diameter outer direction of the said reinforcement core material 3. Doing.

Moreover, the pipe wall part 4 of the said pipe main body 2 is formed in the state expanded previously in the pipe diameter outer direction. Moreover, the shape of the cross section along the tube axis direction of the said reinforcing core material 3 is made into the substantially triangular shape which tapered the edge toward the pipe diameter outer direction, and rounded the top part 3a which protruded in the pipe diameter outer direction Doing. The pipe body 2 is made of low density polyethylene resin, and the reinforcing core material 3 is made of high density polyethylene resin.

In the pipeline rehabilitation tube of the present invention, the tube wall portion of the tube body can be bent so as to protrude in the tube diameter outer direction at the time of the bending, and the tube wall portion in the bent state does not protrude in the tube diameter outer direction than the reinforcing core material. . Therefore, even when inserted into the existing pipeline while bending along the bent portion of the existing pipeline, only the hardened and hard-to-wear reinforcing core material comes into contact with the inner circumferential surface of the existing pipeline. For this reason, it can be inserted smoothly in the existing pipeline which has a curved part, without damaging a pipe main body. When the fluid flows through the inner space of the pipeline regeneration pipe as a new fluid transport space, the pipe wall portion in the bent state does not become a resistance, and thus the pressure loss is not increased during fluid transport.

Further, by forming the tube wall portion of the tube main body in a state in which the tube wall portion is previously expanded in the tube diameter outward direction, and imparting a property that is easily bent outward, the tube wall portion is reliably protruded in the tube diameter outer direction at the time of bending of the pipe regeneration tube. Since it can be bent, the pipe regeneration pipe can be more easily bent.

Further, by making the reinforcing core material into a substantially triangular cross section having a rounded top, a sufficient contact area with respect to the outer circumferential surface of the tube main body can be ensured at the wide bottom portion thereof, and the adhesion strength of the reinforcing core material can be maintained satisfactorily. In addition, at the time of insertion of the rehabilitation pipe, the narrow rounded top portion comes into contact with the inner circumferential surface of the existing pipe, thereby reducing the frictional resistance, thereby making it possible to achieve a smoother insertion.

In addition, when the pipe body is made of low density polyethylene resin and the reinforcing core material is made of high density polyethylene resin, it is possible to obtain a pipe rehabilitation pipe in consideration of the environment in which dechlorinated vinyl is realized.

BRIEF DESCRIPTION OF THE DRAWINGS It is a schematic longitudinal cross-sectional view which shows the sewer pipe rehabilitated by the pipeline rehabilitation pipe which concerns on one Embodiment of this invention.
2 is a partially broken side view of the rehabilitation pipe.
3 is a sectional view of an essential part of a pipeline rehabilitation pipe.
4 is a sectional view of an essential part of a pipeline regeneration tube in a bent state.
It is sectional drawing which shows the state of the pipeline rehabilitation pipe in the bending part of a branch pipe.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The pipeline regeneration pipe 1 which concerns on one Embodiment of this invention is for rehabilitation of the aging sewer pipe 10 as an existing pipeline for fluid transportation.

As shown in FIG. 1, the sewer pipe 10 includes a main pipe 11 embedded in the ground and a branch pipe (attached pipe) embedded in the ground by connecting the main building 11 and a public place 12. (13) is provided. The public place 12 is connected with a drain pipe 14 for guiding the sewage from various facilities such as a building to the public place 12. The main pipe 11, the branch pipe 13, and the drain pipe 14 have a bent portion 15 near the right angle to the element element. In FIG. 1, although the pipeline rehabilitation pipe 1 is inserted in the branch pipe 13 of the sewer pipe 10, and is used for the rehabilitation of the branch pipe 13, not only the branch pipe 13 but also the main building 11 It may be inserted in the inner or drain pipe 14 and used for rehabilitation.

As shown in Fig. 2, the pipe rehabilitation pipe 1 is made of a soft resin (eg, made of a low density polyethylene resin) and a hard resin wound spirally around the outer circumferential surface of the pipe main body (2). A reinforcing core material 3 (for example, made of high density polyethylene resin) is provided. This pipe rehabilitation pipe 1 has an outer diameter including the reinforcing core material 3 slightly smaller than the inner diameter of the paper pipe 13, and is bent while being bent along the bent portion 15 of the paper pipe 13. Flexible to insert

In the tube main body 2, as shown in FIG. 3, the spiral strip | belt-shaped tube wall part 4 (reinforcement core material 3) located between the reinforcement core materials 3 and 3 which adjoin a tube axis direction The tube wall portion 4 excluding the integrated portion is formed in a state in which the tube wall portion 4 is slightly expanded in the tube diameter outward direction in advance, thereby giving the property of being easily bent outward. And as for the pipe wall part 4 of this pipe main body 2, the width dimension L1 of a pipe-axis direction becomes two times or less of the protrusion dimension L2 of the pipe diameter outer direction of the reinforcement core material 3, At the time of bending of the rehabilitation pipe 1, the width direction center part (pipe-axis direction center part) is made into the top part, and it can be bend | folded so that it may protrude in a pipe diameter outer direction.

As shown in FIG. 4, the pipe wall portion 4 in the bent state has a pair of standing pieces 4a and 4a standing up in the tube diameter outer direction. When the pipe rehabilitation pipe 1 is bent to the maximum, the inner surfaces of the standing pieces 4a and 4a are in contact with each other, and the outer surfaces of these standing pieces 4a and 4a are respectively in contact with the reinforcing core materials 3 and 3. It is supposed to be in contact. And the protrusion dimension of the pipe diameter part outer direction of the pipe wall part 4 in this state, ie, the largest protrusion dimension L3, is smaller than the protrusion dimension L2 of the pipe diameter outer direction of the reinforcing core material 3. As a result, the pipe wall portion 4 in the bent state is reliably prevented from protruding in the tube radially outward direction from the reinforcing core material 3, and the pipe regeneration pipe 1 is inserted into the branch pipe 13 having the bent portion 15. Even when inserted while bending, only the reinforcing core material 3 that is hard and hard to wear is always in sliding contact with the inner circumferential surface of the branch pipe 13.

In the reinforcing core material 3, the cross-sectional shape along the tube axis direction becomes a substantially triangular shape with a tapered end toward the tube diameter outer direction, and the top portion 3a protruding in the tube diameter outer direction is rounded. . Thereby, in the wide bottom part 3b of the reinforcement core material 3, the contact area with respect to the outer peripheral surface of the tube main body 2 is fully ensured, and the adhesion strength of the reinforcement core material 3 is maintained favorable. In addition, when the pipeline reinforcement pipe 1 is inserted in the branch pipe 13, the narrow round top part 3a of the reinforcing core material 3 makes sliding contact with the inner peripheral surface of the branch pipe 13, and thus the pipeline regeneration pipe 1 ) Can be inserted smoothly.

Said pipeline regeneration pipe 1 is manufactured as follows, for example. That is, the tube main body 2 is formed by spirally winding a strip of a low-density polyethylene resin and heat-sealing end edge portions adjacent to each other in the tube axis direction in the preceding strip and the subsequent strip. And it manufactures by spirally winding the reinforcement core material 3 made from a high density polyethylene resin about the outer peripheral surface of this pipe main body 2, and heat-sealing the reinforcement core material 3 to the outer peripheral surface of the pipe main body 2. As shown in FIG. As the pipe rehabilitation pipe 1, it is not limited to the above manufacturing method, For example, you may manufacture combining a tubing apparatus and a rotating die suitably.

In order to regenerate the branch pipe 13 using the above-mentioned pipeline regeneration pipe 1, for example, the pipeline regeneration pipe 1 is inserted into the branch pipe 13 from the public place 12 so as to be press-fitted. At this time, the top portion 3a of the reinforcing core material 3 projecting in the outermost direction of the pipe diameter in the pipe rehabilitation pipe 1 is in sliding contact with the inner circumferential surface of the branch pipe 13, but as described above, the reinforcing core material ( Since the top part 3a of 3) is narrowly rounded, frictional resistance is suppressed small and the pipeline regeneration pipe | tube 1 can be inserted smoothly.

In the bent part 15 of the branch pipe 13, as shown in FIG. 5, the pipeline regeneration pipe 1 is bent so that it may follow the bent part 15, and the inner peripheral side of the flexible part of the pipe main body 2 is It is loose and the outer peripheral side of a curved part is extended. At this time, in the bent part inner circumferential side of the tube main body 2, the tube wall part 4 provided with the property which swells previously in the tube diameter outer direction and is easy to bend to the outer side protrudes in the tube diameter outer direction. It is bent, and a corrugated protrusion is formed on the outer side of the tube main body 2. Therefore, when the wastewater flows using the inner space of the pipeline regeneration pipe 1 as a new wastewater transport space, the bent pipe wall portion 4 (wound protrusion) does not become a resistance and causes an increase in pressure loss. There is no work.

In addition, since the pipe wall part 4 (wrinkle-shaped protrusion) of the bending state does not protrude in the pipe diameter outer direction than the reinforcing core material 3 as mentioned above, it will not contact the inner peripheral surface of the branch pipe 13, The damage of the pipe main body 2 at the time of insertion of the pipeline rehabilitation pipe 1 can be prevented reliably.

In this way, after the pipe regeneration pipe 1 is inserted into the branch pipe 13, a filler such as mortar is filled in the gap between the pipe regeneration pipe 1 and the paper pipe 13, and the pipe regeneration pipe 1 ) And the branch pipe 13 are integrated. This filling operation does not necessarily need to be performed, and it is sufficient to just position so that the pipe rehabilitation pipe 1 may not shift in the branch pipe 13.

This invention is not limited to the said embodiment, Of course, many corrections and changes can be added to the said embodiment within the scope of the present invention. For example, the pipeline rehabilitation pipe of the present invention can be used not only for rehabilitation of sewage pipes, but also for rehabilitation of other existing pipes such as a water supply pipe and a gas pipe. In addition, when the pipe reinforcement pipe is bent, if the maximum projected dimension in the pipe radially outward direction of the pipe wall portion in the bent state is smaller than the projected dimension in the radially outward direction of the pipe diameter of the reinforcing core material, the width dimension in the pipe axis direction of the pipe wall portion is necessarily reinforced. You may not make it twice or less of the protrusion dimension of the tube diameter outer direction of a core material, and you may make it twice or more.

One… Pipeline rehabilitation pipe, 2... Tube body; Reinforcing core material, 3a... Top, 4... Tube wall portion 4a... Standing flight, 10... Existing pipeline (sewer pipeline), L1.. Width dimension of pipe wall portion, L2... Protrusion dimension of reinforcing core material, L3... Maximum projected dimension of bent pipe wall

Claims (6)

A reinforcing core material made of hard resin on the outer circumferential surface of the tube body 2 made of flexible resin as the pipe rehabilitation pipe 1 inserted into the existing pipe line 10 and having flexibility for regenerating the existing pipe line 10 ( 3) is wound in a spiral, and the pipe wall portion (4) located between the reinforcing core materials (3, 3) adjacent in the tube axis direction in the pipe main body (2) when bending the pipe rehabilitation pipe (1) Can be bent so as to protrude in the tube radially outward direction, and the maximum projected dimension L3 in the radially outward direction of the tube wall portion 4 in the bent state is projected in the radially outward direction of the reinforcing core material 3. A pipe rehabilitation pipe is characterized in that the pipe wall portion (4) in the bent state protrudes outward from the reinforcing core material (3) by being smaller than the dimension (L2). A reinforcing core material made of hard resin on the outer circumferential surface of the tube body 2 made of flexible resin as the pipe rehabilitation pipe 1 inserted into the existing pipe line 10 and having flexibility for regenerating the existing pipe line 10 ( 3) is wound in a spiral, and the pipe wall portion (4) located between the reinforcing core materials (3, 3) adjacent in the tube axis direction in the pipe main body (2) when bending the pipe rehabilitation pipe (1) Can be bent so as to protrude in the tube diameter outward direction, and the pipe wall portion 4 in the bent state has a pair of standing pieces 4a and 4a standing up in the tube diameter outward direction, and these standing pieces 4a, The inner surface of 4a) abuts, and the protruding dimension L3 of the pipe diameter outer direction in the state which the outer surface of these standing pieces 4a, 4a abuts the said reinforcing core materials 3, 3, respectively, is the said reinforcing core By making the pipe wall portion 4 in the bent state smaller than the protruding dimension L2 in the tube diameter outward direction of the ashes 3, the reinforcing core (3) than the pipe diameter of the channel pipe rehabilitation, characterized in that regulating the projected outward direction. The width dimension L1 of the pipe-axis direction in the pipe wall part 4 of the said pipe main body 2 is a protrusion dimension of the pipe diameter outer direction of the said reinforcement core material 3, A pipeline rehabilitation pipe, characterized in that less than twice (L2). The pipe regeneration pipe according to any one of claims 1 to 3, wherein the pipe wall portion (4) of the pipe main body (2) is formed in a state in which the pipe wall portion (4) is previously expanded in a pipe diameter outward direction. The shape of the cross section along the tube axis direction of the said reinforcement core material 3 is made into the substantially triangular shape which tapered the edge toward the tube diameter outer direction, and the tube diameter in any one of Claims 1-4. A pipe rehabilitation pipe, characterized in that the top portion (3a) protruding in the outward direction is rounded. The pipe regeneration pipe according to any one of claims 1 to 5, wherein the pipe main body (2) is made of low density polyethylene resin, and the reinforcing core material (3) is made of high density polyethylene resin.

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