GR1008995B - Three-layered drain composed of a corrugated double-structured geofabric-coated tube - Google Patents

Abstract

Novelty: a three-layered drain tube composed of a corrugated double-structured geofabric-coated tube is disclosed buried into a trench for collecting and removing waters (drainage applications). Constitution: for avoiding the obstruction of the draining holes (4) of the drain tube by non-organic and organic admixtures, the drain tube is covered with adequate permeable synthetic filter (5) manually set during installation and presenting a string of technical and economy-related problems. Purpose: the aim of the invention is to produce a tube where the geofabric will be incorporated in a steady and suitable manner during the production phase by creating a three-layered tube able to efficiently facing the disadvantages presented during the manual covering of the corrugated drain tube with the synthetic geofabric.

Description

Three-layer drainage pipe consisting of double-wall structured corrugated pipe covered with geotextile

The invention relates to double-walled corrugated pipes which are used in drainage applications and are covered with geotextile. The geotextile is placed in such a way that it covers the drainage pipe circumferentially and along its entire length as an additional outer layer.

Corrugated drain pipes are used in drainage projects. The works in question are carried out for the collection and removal of groundwater as well as filtered surface water. In these installations the drainage pipes are buried in a trench. Drainage pipes are usually corrugated and are perforated, plastic pipes of different diameters depending on the drainage surface and the flow required in each case.

To avoid clogging of the pipe's drainage holes by inorganic and organic impurities, the pipe is covered with a suitable permeable synthetic filter. Covering the drain pipe with the permeable filter is done manually during installation. More specifically, as the pipe is placed inside the trench, the geotextile is placed around it at the same time. This method has several disadvantages.

A major disadvantage is the large expenditure of time and effort because the installer will have to manually cover the perimeter of the drainage pipe with the synthetic geotextile by wrapping it around it.

Another disadvantage is that when wrapping the synthetic geotextile around the pipe there is an overlap of the geotextile which is larger in some places and smaller in others. This results in the geotextile having a different drainage capacity at the points where there is overlap, thus degrading the drainage effect.

A further disadvantage of the manual way of laying the geotextile is the large waste of geotextile due to overlapping of the layers as mentioned above.

Another disadvantage of the manual method of covering the drainage pipe with geotextile is the fact that the geotextile is not firmly placed on the pipe since it is usually not possible to use glue or any other method of stabilizing the geotextile, as a result of which the geotextile leaves its position and it leaves the drain pipe uncovered and therefore the drain holes are not protected, they become clogged in a short time, thus reducing the drainage capacity of the pipe.

Also the drainage pipes used are single wall corrugated pipes. This has the result that the inner surface of the pipe, which is also the water flow surface, is also wavy, making it difficult for the water to drain.

According to the present invention, in the three-layer drainage pipe consisting of a double structured wall corrugated pipe covered with geotextile, the geotextile is placed in a specially designed machine in which the geotextile is placed and as the corrugated pipe passes through the machine, during of its production, is covered with geotextile. The geotextile laying machine has a system for gluing the edges of the geotextile so that it covers the corrugated pipe safely during its production, storage and installation. The gluing of the edges of the geotextile is done either by heat gluing or by ultrasonic gluing.

Finally, it is important that the drainage pipe is double-walled with the result that the inner surface of the pipe is smooth. Thus the easier flow of the drained water is achieved

The purpose of the present invention is to produce a pipe that the placement of the geotextile will be integrated in a stable and even manner during its production, creating a three-layer drainage pipe consisting of a double-walled corrugated pipe covered with geotextile. Laying the geotextile in this way has a number of advantages.

The main advantage is the saving of installation time of the pipe in question since it will not be necessary to wrap it with geotextile in the project but only to place it inside the trench.

The way the geotextile is placed on the drainage pipe ensures a constant drainage capacity since there will be no overlapping of the geotextile layers.

An additional advantage is the saving from the correct consumption of the geotextile since the width of the geotextile strip will be as needed to cover the pipe perimeter plus the geotextile bonding surface

An important technical advantage is also that the geotextile covers the drainage pipe firmly and in a way that it cannot leave it uncovered since it is glued along its entire length.

It should also be noted that the edges of the geotextile are only glued to each other and not to the pipe. This allows the user to be able to easily remove the geotextile at any point in the pipe desired in order to fit a fitting.

Finally, the three-layer drainage pipe consisting of a double-wall structured corrugated pipe covered with geotextile as it has a smooth inner layer allows for optimal water drainage compared to single-wall corrugated drainage pipes.

Below is a brief explanation of simplified drawings which are intended to assist in a thorough understanding of the subject invention.

Figure 1 shows the longitudinal section of the corrugated double wall structured drainage pipe (1) which does not have a geotextile cover. More specifically, the outer, wavy wall (2) of this can be seen. Also visible is the inner smooth wall (3) and finally the slits (4) through which the water flows into the inside of the pipe to be drained.

Figure 2 shows, on a different scale, a side view of the three-layer drainage pipe consisting of a double-wall structured corrugated pipe covered with geotextile. More specifically, the corrugated double wall structured drainage pipe (1) which is partially covered with geotextile (5) is shown. As can be seen, the geotextile (5) covers the entire circumference of the pipe (1) and its two ends (6) are glued together either by heat welding or by ultrasonic welding, creating a longitudinal weld (7). After gluing (7) and above, the two edges of the geotextile (6) are left over.

Figure 3 shows the machine for placing the geotextile around the corrugated double-wall structured drain pipe in order to produce the three-layer drain pipe consisting of the double-wall structured corrugated pipe covered with geotextile.

The double wall structured drainage pipe (1) which is produced using the appropriate upstream equipment, is led to the geotextile laying machine as shown in figure 3.

The geotextile laying machine can be in-line with the rest of the production line equipment of the corrugated double wall structured drainage pipe (in-line). Alternatively, it can be used off-line. In the case of installation outside the production line (off-line), the corrugated double-walled drainage pipe (1) is initially produced and temporarily packaged, and then, in a second time, its passage through the geotextile installation machine and its repackaging .

The geotextile placing machine has the ability to be fed with geotextile alternatively from two stations (8.1) and (8.2) which it carries in its lower part so that in case the geotextile runs out at one station, its supply can continue immediately with the second without affecting production.

The geotextile (5) is led open (flat) towards the inside of the machine by means of guide rollers. As it passes through the machine, it is simultaneously supplied with the double-walled structured drain pipe (1). The geotextile enters under the pipe (1) and at the same time is folded to cover it laterally with the help of the guide (9). The guide (9) is a pair of two suitably shaped pieces of sheet metal which are located on either side of the drainage pipe (1) to guide the pipe on the one hand, and on the other hand to shape the geotextile (5) to cover the pipe laterally.

The advancement of both the pipe (1) and the geotextile (5) is ensured by the two pairs of crawlers (10.1) and (10.2). Then the drainage pipe (1) and the geotextile (5) are guided into the gluing device (11). The gluing device (11) has guides which ensure that the two edges (6) of the geotextile come into contact. As the two edges of the geotextile are in contact, they pass through a thermo-adhesive head which is heated through an electrical resistance. The thermo-adhesive head heats the geotextile and at the same time exerts pressure on the two ends (6) of the geotextile (5) resulting in their gluing. Alternatively, an ultrasonic bonding head can be used instead of the thermal bonding head, resulting in the bonding of the two edges of the geotextile in a similar way. After the tube exits the welding device (11) it is longitudinally welded (7).

The piece of geotextile that is left over the glue (7) and up to its edge must have a certain width. For this reason, the excess piece must be removed. In order to achieve this the drainage pipe (1) as covered with the geotextile (5) is passed through the excess geotextile cutting device (12). The device (12) has rotating knives which, depending on their setting, remove a specific width of the excess geotextile (13). This strip of geotextile is rolled and collected in the roll (14).

Finally, the three-layer drainage pipe consisting of a double-walled corrugated pipe covered with geotextile exits the machine and is ready for packaging and disposal.

Claims (7)

1. The three-layer drainage pipe consisting of a double-wall structured corrugated pipe covered with geotextile is characterized by the fact that the two edges (6) of the geotextile are glued together 2.   The three-layer drainage pipe consisting of a double-wall structured corrugated pipe covered with geotextile as mentioned in claim 1 is characterized in that the two edges of the geotextile (6) can be glued together by heat-gluing. 3. The three-layer drainage pipe consisting of a double structured wall corrugated pipe covered with geotextile as mentioned in claims 1 and 2 is characterized in that the two ends of the geotextile (6) can be ultrasonically glued together. 4. The three-layer drainage pipe consisting of a double structured wall corrugated pipe covered with a geotextile as claimed in claims 1-3 is characterized in that the two edges of the geotextile (6) are glued only to each other and not to the double structured wall corrugated drainage pipe (1) 5. The machine for placing the geotextile around the corrugated drainage pipe (1) as referred to in claim 1 is characterized in that it has two stations for placing the geotextile rolls (8.1) and (8.2), that it can carry a head with resistance for thermal bonding of the geotextile (5), that it can alternatively carry a head for gluing the geotextile with ultrasound and that it has a device (12) for removing the excess of the geotextile (13) 6. The machine for placing the geotextile around the corrugated drainage pipe (1) as referred to in claim 5 can also be used off-line of the corrugated double wall structured drainage pipe 7.   The machine for placing the geotextile around the corrugated drainage pipe (1) as mentioned in claims 5 and 6 can be used in-line with the rest of the equipment of the production line of the corrugated double wall structured drainage pipe.