WO2007118894A1

WO2007118894A1 - Dewatering and/or drainage device

Info

Publication number: WO2007118894A1
Application number: PCT/EP2007/053798
Authority: WO
Inventors: Bernd Hewing; Frank Dirkskötter
Original assignee: Hewitech Gmbh & Co. Kg
Priority date: 2006-04-18
Filing date: 2007-04-18
Publication date: 2007-10-25
Also published as: AU2007239489A1; EP2007949B1; DE112007000119A5; EP2007949A1

Abstract

A dewatering and/or drainage device (10) is provided with a grate structure, through which extends a passage (20) for the inlet of liquid which is to be drained. The grate structure is composed of at least three and preferably four in particular identical parts (12) through which extend grate openings (18) which run in each case parallel to one another and which run from the inner side (22) of the passage (20) to the outer side of the grate structure.

Description

Drainage and / or drainage device

The invention relates to a drainage and / or drainage device (hereinafter called dewatering device), as used for example for the infiltration of surface water.

It is known to introduce surface water into underground cavities which are filled by lattice structural elements. An example of such a dewatering device can be found in DE 20 2004 018 319 Ul and in DE 299 24 050 Ul.

The known dewatering devices have a box-shaped structure and are usually made of plastic. They are manufactured in injection molding technology. Since the known dewatering devices are flowed through three-dimensionally, they have in several directions extending openings. If such lattice structures are produced by injection molding, this means complicated sliding technology and complex injection molds because of the criss-cross lattice openings. For this reason, described in the already mentioned above DE 299 23 050 Ul to produce a drainage box from two equal half-boxes. However, the production of a half-box already requires a complex slide and injection molding technique.

The object of the invention is to provide a drainage and / or drainage device that can be produced inexpensively and without much effort in injection molding.

To solve this problem, a drainage and / or drainage device is proposed with the invention, which is provided with a lattice structure through which a passage for the admission of infiltrated liquid to extend, wherein the lattice structure of at least three and preferably four in particular equal parts through which each extending parallel to each other extending grid openings extending from the inside of

Passage extend to the outside of the grid structure.

According to the invention, the dewatering device is made up of at least three parts, each part having gate openings extending substantially in one direction. Such a Gittereiement can be produced in a very simple way in injection molding, since no slides are required for demolding, but the demolding is done automatically by moving apart of the injection molds. These Gätterelemente are placed together, which takes place for example by snap-in connections, gluing or welding or separate fasteners. At least three of these elements together constitute the dewatering device according to the invention, wherein the lattice openings of each element in a circumferential swing corresponding to the pitch! offset from one another (120 ° for three-part and 90 ° for four-part lattice structure).

According to the invention, therefore, the box or tubular dewatering device is made of several, in particular equal parts, through which grid openings extend, all of which run parallel to each other per part. Preferably, for example, an eight-part lattice structure can also be constructed with these parts. The division is done every 45 °. When the grid structure has an outer box shape, each side of the grid structure has two equal parts which abut each other in the center and are mitered at the corners to a respective adjacent part of the grid structure. The miter arrangement is expediently also given a four-part design of the grid structure. To increase the stability of the box or tubular dewatering device according to the invention, it is advantageously provided to provide a support wall in the passage, which wall supports itself in diametrically opposite regions of two parts of the lattice structure. As a result, pressure forces can be absorbed depending on the height of the soil above the dewatering device embedded in the soil. The stucco wall can thus be oriented vertically (but also horizontally in the installation position of the drainage device). In the latter case, the supporting wall stabilizes the lattice structure of the dewatering device according to the invention against laterally applied earth pressures. The stucco wall may be open, for example, as a grid structure, or be formed closed. In other words, the support wall can thus have through holes. The attachment of the support wall at their contact surfaces with the relevant parts of the lattice structure can be made by snapping or by another frictional connection düng.

The invention will be described below with reference to the drawing with reference to several different embodiments. In detail, they show:

1 is a perspective view of a first Ausführungsbetspiels a box-shaped dewatering device with four identical lattice structural parts,

2 is a plan view of one of the grid structure elements according to II of Fig. 1,

3 shows an alternative embodiment of a four-part grid structure with respect to the embodiment of FIG. 1 different division, Fig. 4 is a round dewatering device in tubular form with four equal lattice structural parts and

5 shows a perspective view of an eight-part lattice structure dewatering device.

The Fign. 1 and 2 show a first Ausfuhrungsbeispie! a box-shaped dewatering apparatus 10 having a grid structure composed of four natural grid structure parts 12. Each lattice structure part 12 has a plurality of intersecting longitudinally and transversally running lattice struts 14, 16 on _f between which lattice openings 18 are formed. The four lattice structure parts 12 form between them and each other a passage 20 _f which extends longitudinally through the box-shaped dewatering device 10. Openings 24 are located on the inner side 22 of the passage 20 with the grid openings 18. In the installed state, a nonwoven (in particular Geotext ™) is placed around the dewatering device 10 in order to cover the grid openings 18 to the outside. This prevents soil from entering the lattice structure.

The water to be infiltrated is led via discharge pipes (not shown) into the passage 20, where it penetrates via the openings 24 into the lattice openings 18 and their openings and finally spreads over the entire dewatering device 10. Several dewatering devices according to Figs. 1 and 2 may be arranged side by side, above and behind each other, wherein adjacent dewatering devices may be secured against unintentional relative displacements by pin-hole connections, separate connection elements or in another manner.

The advantage in the production of the dewatering device 10 according to FIGS. 1 and 2 can be seen in that the dewatering device 10 is composed of four parts, wherein each lattice structure part 12 can be produced in a simple manner by injection molding. ments 18 of each lattice structure 12 paralle! extend to each other, the demolding of the injection-lattice Strukturteifs 12 can be done by simply Auseinaπderfahren the Spritzgussforrnhäiften. A slider technique o. Dgi. Complex demolding technique is not required.

In Fig. 3 is also a box-shaped dewatering device 10 'is shown, in which the individual components of the dewatering device 10 according to FIGS. 1 and 2 corresponding elements with the same reference numerals as in FIGS. 1 and 2 are designated. The difference between the dewatering device 10 'and the dewatering device 10 of FIGS. 1 and 2 is the subdivision of the dewatering device into the individual lattice structure parts 12. While these parts 12 are shown in the embodiment of FIGS. 1 and 2 extend along the edges of the box-shaped dewatering devices 10 and are thus relatively flat, the lattice structure parts 12 in the dewatering device 10 'of FIG. 3 run at a corner, so that for producing a lattice structure part 12 of the dewatering device 10' a slightly higher Injection mold is required as in the case of Ausführungsbeispieis according to FIGS. 1 and 2,

4 shows an exemplary embodiment of a round or tubular dewatering device 10 ". Here too, those elements that are identical or identical to the elements of the exemplary embodiments of FIGS. 1 to 3 are identified by the same reference symbols, each grid structure part 12 extends in the embodiment of FIG. 4 over a Winkeibe- range of 90 °,

5 shows a further exemplary embodiment of a box-shaped dewatering device 10 '"The grid structure of this dewatering ^device 10"' likewise has four identical lattice structure parts 12, which are in turn constructed of intersecting lattice struts 14, 16. In this

Embodiment, the grid openings 18 are in turn open to the passage 20 through openings 24. The connection of the lattice structure parts 12 of the previously described exemplary embodiments of the dewatering device is preferably carried out by welding, gluing or by locking adjacent lattice structure parts by means of latching or Verbindungselernente, The connection structure must be such that they act on the static loads that affect the dewatering device via the soil, withstand.

In the figures described above, the individual lattice structure parts 12 each have a symmetrical lattice structure. It should be mentioned at this point that the grid structure can advantageously also be asymmetrical (with respect to a longitudinal axis extending or transverse thereto symmetry axis), It is also possible at lower expected in the installed state loads the lattice structure parts 12 of the figures in turn each of two to assemble the same components as shown in FIGS. 1 and 5 is indicated at 25 indicated. This would z. For example, the drainage devices of FIGS. 1 and 5 consist of eight equal lattice structural parts (symmetrical division of the parts assumed in the longitudinal extension of the passages).

In addition, a support wall 26 may be disposed in the passage 20, as shown. The support wall 26 is provided in this embodiment with through holes, which form as openings between adjacent lattice struts of the support wall 26. The support wall 26 supports two opposing lattice structure parts 12, whereby the stability of the Ent- washing apparatus 10 '"is increased.

Claims

A drainage and / or drainage device having a grid structure through which extends a passage (20) for admission of liquid to be seeped, the grid structure consisting of at least three, and preferably four, in particular equal parts (12), through each of which extending parallel to each other grid openings (18) extending from the inside (22) of the passage (20) to the outside of the grid structure.

2. drainage and / or drainage device according to claim 1, characterized in that the grid structure of eight equal parts (12) is constructed

3. Drainage and / or drainage device according to claim 1 or 2, characterized in that the composite parts (12) between them define the passage (30) through the grid structure-

4. Drainage and / or drainage device according to one of claims 1 to 3, characterized in that each part (12) has a rounded lattice structure.

5. Drainage and / or drainage device according to one of claims 1 to 4, characterized in that adjacent parts (12) are connected at their contact surfaces, in particular by gluing, welding or by means of connecting elements.

6. Drainage and / or drainage device according to one of claims 1 to 5, characterized in that in the passage (20) between two parts (12) of the grid structure, a support wall (26) extending in diametrically opposite areas of the two Parts (12) supported on these.

7. drainage and / or drainage device according to claim 6, characterized in that the support wall has passage recesses.