EP1210543A1

EP1210543A1 - Method and device for refurbishing the leaky walls of conduits having small diameters

Info

Publication number: EP1210543A1
Application number: EP00956268A
Authority: EP
Inventors: Christian Noll; Thomas Reutemann
Original assignee: UV Reline Tec GmbH and Co
Current assignee: UV Reline Tec GmbH and Co
Priority date: 1999-09-09
Filing date: 2000-07-25
Publication date: 2002-06-05
Also published as: WO2001018444A1

Abstract

The invention relates to a method for refurbishing the leaky walls of horizontal, vertical or inclined conduits having small diameters up to a nominal diameter of approximately DN 200. Refurbishing is carried out by introducing a fibre tube that is impregnated with a UV-hardenable resin into the conduit. The tube is mounted, preferably under pressure, in such a way that said tube rests on the inner wall of the conduit. One or more UV-light sources are led through. UV-light is emitted from the light sources and onto the fibre tube, whereby the resin is hardened. An artificial resin, especially a styrene-free epoxy acrylate resin, that does not limit the functions of thermoplastic inner films is used for impregnating the fibre tube.

Description

Method and device for repairing the leaky walls of pipelines with small diameters

The invention relates to a method and a device for the renovation of leaky walls of horizontal, vertical or inclined pipelines with small diameters up to a nominal diameter of approximately DN 200.

Damage occurs especially in small cables. Due to the damage, i.e. leaky pipes, for example, water or waste water. Especially in the case of horizontal and vertical pipes in nominal widths up to DN 200 installed in the house, access is often impossible. The damage can only be remedied by prying open the walls or digging up.

In order to remedy damage or leaks that have occurred on the pipe walls, methods are known in which a hose impregnated with synthetic resin is used to line the pipes. The synthetic resins used, in particular epoxy resins, are cold-curing. A disadvantage of these methods is that due to the cold hardening, the hoses have to be impregnated on site and installed in a short time. Otherwise, the synthetic resin hardens prematurely before it is ready for installation in the pipe. This has a particularly negative effect on pipes in the house area, since the prematurely hardened material is very difficult, if at all, to remove from the pipe to be renovated. In processes with long curing times of the synthetic resin used, the unusability of the cables in houses is a major disadvantage. With UV curing is As is well known, hardening is possible in minutes and ensures that the lines can be put back into operation in the shortest possible time.

Processes based on UV light curing, which are used in main channels with large diameters, cannot be used in small bendable pipes. The curing device, called the radiation source, does not allow driving through and uniform curing in the arch region. The UV lamps used, with outputs of 400 watts and more, radiate too high temperatures to be used in small diameters. The mostly laminated thermoplastic films on the inner surface of the hoses do not allow these temperatures, because under these conditions the commonly used resins such as unsaturated polyester resins (UP resins) and vinyl ester resins (VE resins) swell the inner film due to their styrene content, so that they swell detaches from the film tube and sticks at high temperatures, especially to pipe bends with a small radius. It is then almost impossible to pull the inner film, mostly composite film PE / PA (polyethylene / polyamide), out of the small lines after curing. If left in the pipes, however, this would lead to blockages or drainage obstacles.

The known methods are mostly used where there are two accesses to the line, ie the hose is drawn into the line, from one opening to a second. These are not available for small lines, primarily house connection lines or the like. The invention is based on the object of proposing a method and a device with which the damaged small lines with diameters up to approximately DN 200 can be brought back into a proper, ie primarily leak-proof condition by lining them with a light-curing synthetic resin-impregnated hose. The hose can be installed both horizontally and vertically, such as in roof drainage pipes. Arches can also be renovated.

This object is achieved in that a synthetic resin which does not restrict the functions of the thermoplastic film, in particular its adhesiveness and stretchability, is used to impregnate the fiber tube.

In particular, the use of the acrylic resin, primarily based on styrene-free epoxy acrylate resins, has the advantage that hoses with laminated thermoplastic films can be used, since these do not swell and have to be pulled out of the tube after curing. Pulling out the inner film is difficult or impossible for cables with bends. The epoxy acrylate resins preferably contain no solvents, at most acrylic esters, which do not restrict the functions of the laminated thermoplastic films. On the other hand, it is also conceivable to adjust the properties of the films used to the resins used. For example, composite films PE / PA / PE could also be laminated onto the hoses and thus a barrier against the solvent styrene could be used. Other combinations of composite films are also conceivable. It starts with the impregnation of the hose, which consists of a stretchable hose, which is covered with a stretchable film. The hose consists of a textile material, preferably needle felt, polypropylene or a fleece made of chemical fibers. It is also conceivable that the material is based on glass fiber, in the form of woven fabrics, knitted fabrics, knitted fabrics, mats or combinations thereof. The covering films are thermoplastic films, preferably made of polyurethane (PUR), polyethylene (PE), polyamide (PA), polypropylene (PP) or polyvinyl chloride (PVC), as well as composite films made of them. Hoses and foils mostly form a technical network. The film can also only act as a protective film that is not connected to the hose beforehand. The impregnation can be carried out with any UV-curing synthetic resin that does not restrict the functions of the thermoplastic films used. Styrene-free, in particular solvent-free, epoxy acrylate resins are preferred.

After impregnation, it is introduced into the pressure chamber with which the hose inverts into the damaged channel, i.e. is turned in. The radiation source is then brought to the end of the hose. This process takes place while maintaining the inversion pressure via a lock. This can be done with suitable push cables or rods as well as with the help of a drive of the wheels or by pulling.

Due to the special structure of the radiation source, this construction allows an arc movement. Conventional radiation sources or UV curing technology for larger pipe diameters are not suitable for bends in these diameter ranges. As soon as the radiation source has reached the end of the channel, the UV lamp or lamps are ignited so that the curing reaction in the resin can begin. The radiation source is pushed or pulled at defined speeds with the help of a motor in the direction of the pressure chamber. As soon as the radiation source has reached the beginning of the channel, any closed inlets and the end of the hose are opened again using a milling robot.

The invention is explained in more detail in the following description with reference to exemplary embodiments shown in the drawings.

Show it,

Fig. 1 shows a longitudinal section through a device according to the

Invention for a version with a short overall length,

Fig. 2 shows an embodiment of the device with a

Spring connection articulated front part and end part.

3 shows the device with an elastomer buffer between the front part and the end part,

4 is a view of the device with a ball joint between the front part and the end part, Fig. 5 is a view of the device with coil springs between the spacers and

Fig. 6 is a view of the device consisting of several coupled units or modules.

The device shown in FIG. 1 has a front part 10 and an end part 11, which are connected to one another by means of bent tubes 6. On the front part 10, a built-in connector 7 is provided for a camera 3 in the axial direction, and axially sprung guide wheels 1 are also attached, these guide wheels 1 being supported on springs 13. Three such wheels are expediently provided, each offset from one another by an angle of 120 °, so that a central guidance of the device in a pipeline 23 is ensured.

On the end part 11, a lamp holder 12 is attached, in which a UV lamp 2 is inserted, which is supported at its front tip on an axially sprung lamp holder 4. The end part 11 is provided with corresponding wheels 1. According to the displacement of these guide wheels 1, they can assume a position 9 for a minimum outside diameter and a position 8 for a maximum outside diameter. Furthermore, there is a connection socket 5 for a push cable on the end part 11. The bent tubes 6 have the task of largely excluding a shadow effect, so that the inner wall of the pipeline 23 is evenly irradiated by the UV lamp 2. 2, the front part 10 is divided into two sections 14, 15 and between these two sections 14, 15 there is a spring connection 16.

3 shows a similar embodiment, an elastomeric buffer 17, for example in the form of a block, being located between these sections 14, 15.

In the further embodiment according to FIG. 4, a ball joint 18 is arranged between the sections 14, 15.

As FIG. 5 shows, coil springs 19 can also be provided as spacers for springing the wheels 1. As shown in FIGS. 2 to 4 and 6, the individual guide wheels can also be arranged on spring arms 24, the front part 10 and the end part 11 each being assigned two such wheels 1 in one plane.

The device shown in Fig. 6 is composed of two units 20 and 21, i.e. two identical modules which are connected to one another at a joint 22. This results in the advantage that the device can be moved faster through the pipeline 23 and, in addition, there is a safety reserve because of the two lamps 2 present if one of the lamps fails.

Claims

claims

1) Process for the rehabilitation of the leaky walls of horizontal, vertical or inclined pipelines with small diameters up to a nominal diameter of about DN 200 by inserting a fiber hose soaked with a UV-curable resin and laminated on the inside with a thermoplastic film into the pipe .

Widening of the tube, preferably under pressure, so that it bears against the inner wall of the tube, carrying out one or more UV light sources, emitting UV light from the light sources onto the fiber tube, whereby the resin is cured, characterized in that for Impregnation of the fiber hose, a synthetic resin that does not restrict the functions of a thermoplastic film is used.

2) Method according to claim 1, characterized in that a styrene-free epoxy acrylate resin is used as the synthetic resin.

3) Method according to claim 1, characterized in that thermoplastic films are used to cover the inner surface of the tube, which cause a barrier to the solvent of the resin.

4) Method according to claim 1 to 3, characterized in that the UV light source is pushed through the tube, pulled or moved self-propelled. 5) Method according to claim 1 to 4, characterized in that the UV light source is drawn in with the insertion of the fiber tube to the end of the tube.

6) Device for performing the method according to claims 1 to 5, with a UV lamp as the light source, which is arranged on a moving along the axis of the tube chassis, the chassis has guide wheels, characterized in that with a short length Front part (10) is connected to an end part (11) such that the UV lamp (2) is inserted into a lamp holder (12) at the end part (11) and is supported on an axially sprung lamp holder (4) on the front part (10).

7) Device according to claim 6, characterized in that the front part (10) and the end part (11) are connected by means of bent tubes (6).

8) Device according to claim 6 or 7, characterized in that the front part (10) or the end part (11) are formed in two parts and the two sections (14, 15) are articulated together.

9) Device according to claim 8, characterized in that a spring connection (16), an elastomer buffer (17) or a ball joint (18) are arranged between the sections (14, 15).

10) Device according to claim 6 to 9, characterized in that the guide wheels (1) are radially cushioned. 11) Device according to claim 10, characterized in that spiral springs (19) are provided as the suspension.

12) Device according to one of claims 6 to 11, characterized in that at least two such units (20, 21) are connected to one another at joints (22).

CHANGED REQUIREMENTS

[Received at the International Bureau on December 22, 2000 (December 22, 2000); original claims 1-12 changed (3 pages)]

1) Process for the renovation of the leaky walls of horizontal, vertical or inclined water or sewage pipes with small diameters up to a nominal size of about DN 200 by inserting a fiber hose soaked with a UV-curable resin and laminated on the inside with a thermoplastic film into the pipe.

Widening of the tube, preferably under pressure, so that it rises on the inner wall of the tube, performing one or more UV light sources, emitting UV light from the light sources on the fiber tube, whereby the resin is cured, characterized in that for Impregnation of the fiber hose is used, a styrene-free epoxy acrylate resin which does not restrict the functions of a thermoplastic film.

2) Method according to claim 1, characterized in that a solvent-free epoxy acrylate resin is used as synthetic resin.

6) Device for performing the method according to claims 1 to 5, with a UV lamp as a light source, which is arranged on a moving part along the axis of the tube, the chassis having guide wheels, characterized in that with a short overall length Front part (10) is connected to an end part (11) such that the ÜV-Larnpe (2) is inserted into a lamp holder (12) at the end part (11) and is supported on an axially sprung lamp holder (4) on the front part (10).