EP2816163A1 - Drainage gutter - Google Patents

Abstract

A drainage channel for drainage of surfaces, especially traffic areas, the task is based on creating a drainage channel with an increased absorption capacity with the same nominal width. This is achieved by the design of a so-called multi-deck trough (1), in which a plurality of drainage cross-sections (2, 3) are arranged one above the other, wherein the drainage cross-sections (2, 3) through one or more opening (s) in the trough sole (5) of each Upper drainage cross-section (2) are fluidly connected to each other such that at least when exceeding a defined hydraulic pressure, the introduced surface water through both drainage sections (2, 3) can be discharged.

Description

The invention relates to a drainage channel for drainage of surfaces, in particular of traffic areas.

Such a drainage channel is for example from the German utility model DE 8807015 U1 previously known. Typically, such drainage channels consist of a channel cross-section with two spaced-apart side walls, which are closed on the underside by a sole section and usually complement each other to form a preferably U-shaped drainage cross section. The side walls of the channel are usually closed on the upper side by a frame in which a gutter cover can be inserted, which closes the drainage channel on top. Usually, the drainage channels are inserted into a prepared dewatering trench, for which purpose the sole section of the dewatering cross section is under attack by a flat installation surface and thus can be easily inserted into the dewatering trench. In this case, the actual gutter body of the drainage channel is increasingly made of plastic in today's time, wherein the drainage trench is further filled with a gutter enclosing in-situ concrete. The in-situ concrete is often not filled up to the top of the cover, but only up to a much lower level to still apply a road surface or at least a pavement can, which then in the installed position at least approximately closes with the upper edge of the gutter cover received in the frame.

If properly understood, therefore, the channel body made of plastic can be considered more or less as lost formwork in situ concrete.

The discharged in the drainage channels water is usually fed by a natural gradient to a gully, via which then the introduced and discharged surface water is fed to an underlying sewer system.

In particular, in connection with the drainage of traffic areas, it is often necessary that, in contrast to the actual gutter body, the gutter cover is designed as a cast grate, for example, in order to be able to dissipate the introduced surface loads. The most expensive part of a drainage channel is therefore regularly the gutter cover. The costs of the gutter cover depend very much on the nominal width of the drainage channel. In particular, in connection with the drainage of traffic areas there is the additional problem that in addition to the high loads introduced due to the size of the usually sealed surfaces a high absorption capacity and thus a large nominal diameter of the drainage channels used is required. Normally, the nominal diameter is directly proportional to the dewatering capacity of the drainage channel. A gutter with a larger nominal size usually also has a higher absorption capacity. As already stated, this is regularly associated with significantly higher costs of the gutter in question.

Based on this prior art, the invention is based on the object, with unchanged nominal diameter of a drainage channel to create a drainage channel with a significantly increased absorption capacity.

The object underlying the invention is achieved by a drainage channel having the features of the current claim 1. Advantageous developments of the channel according to the invention can be found in the dependent claims 2 to 9.

According to claim 1, the drainage channel according to the invention is designed as a so-called multi-deck trough. This is to be understood that below a conventional, preferably U-shaped drainage cross-section another, also preferably U-shaped drainage cross-section is arranged, wherein the two drainage cross sections are connected by means of an opening in the respectively arranged between the two drainage cross-sections trough sole. Due to the fact that at least one additional additional drainage cross-section is arranged beneath a gutter cover with an unchanged nominal width, the hydraulic swallowing capacity of the gutter is almost doubled with the nominal width unchanged. By additional, further below arranged drainage cross sections, which in turn are connected by openings with the respectively above arranged drainage sections, the absorption capacity, again with unchanged nominal width of the drainage channel, can be further increased. It should be noted that the additional costs for the increased absorption capacity are relatively low, since the additional drainage cross sections can be realized with relatively inexpensive additional plastic cross sections. In other words: with one and the same gutter cover, far greater drainage capacities than previously imaginable can be implemented at low additional costs.

In concrete realization usually sits the upper drainage cross-section each underside concluding sole region, which in turn is attacked by an at least largely flat footprint, at least indirectly on the frame of the lower side subsequent, each lower drainage cross section. As already mentioned, the two drainage cross sections are through openings in the sole region of the respective upper drainage cross section fluidly connected to each other, so that the entering into the upper dewatering cross section through the gutter cover surface water can be introduced directly into the underlying additional drainage cross section and also removed.

In a further embodiment of the connection between the upper and lower drainage cross-section, the footprint can be extended by means of side bars arranged on both sides, wherein the side bars are mounted in the installed position on the frame of the respective lower drainage cross-section.

In a further embodiment of the connection of the individual drainage cross sections, the side bars can be detachably or irreversibly connected to the frame of the respective additional channel cross-section arranged below by means of suitable connecting means, such as rivets or screws.

In a further development of the invention, the openings or a single opening in the sole region of the mounting position in each case upper cross section of the multi-deck trough are each provided with a closure which opens automatically as a result of the respective upcoming hydraulic pressure and, as soon as the set pressure level falls below again is, also automatically closes again. This automatically controlled closure ensures that the deeper drainage cross-sections are only used if the need arises, but that they are certainly also available during heavy rainfall. A side effect of this controlled closure is also that only with corresponding hydraulic pressure and thus also with a sufficient flow over the individual drainage cross sections, a further underlying drainage cross section is provided. This ensures a sufficient flow through the individual drainage cross sections, which is necessary, for example, for the self-cleaning of the individual drainage cross sections.

In a concrete embodiment, this development may be implemented, for example, by a closure with a spring-driven closing flap, wherein the spring constant of the spring-driven closing flap is to be selected as a function of the above-described hydraulic pressure level.

In terms of design, it has proven useful if the nominal diameters of the drainage cross sections of the multi-level trough arranged one above the other extend from top to bottom in order to enable secure positioning of the multi-level trough in a drainage ditch and, moreover, for the required static safety of the multi-level trough to care.

In an advantageous embodiment of this initially provided for static reasons dimensioning of the individual drainage cross-sections results in a further advantage in that the individual drainage cross sections of the multi-deck trough, at least with disassembled side bars, for example, for the purpose of storage and / or transport, are stackable. The multi-level trough can therefore be provided with a very low storage and transport volume.

In an advantageous embodiment, the multi-floor trough is usually, apart from the gutter cover, completely or at least predominantly made of plastic.

The invention will be explained below with reference to some exemplary embodiments chosen only by way of example, wherein the exemplary embodiments do not limit the scope of protection of the subject-matter of the application, which is defined solely by the wording of the valid patent claims.

Figur 1

eine Mehrstockrinne in einer perspektivischen Ansicht,

Figur 2

die in Fig. 1 gezeigte Mehrstockrinne in einer Querschnittansicht,

Figur 3

die in Fig. 1 und 2 gezeigte Mehrstockrinne in einer perspektivischen Ansicht in Verbindung mit einem Anschluss an die Kanalisation,

Figur 4

eine weitere Mehrstockrinne in einer perspektivischen Ansicht und

Figur 5

die in Fig. 4 gezeigte Mehrstockrinne in einer Querschnittansicht.

Show it

FIG. 1

a multi-level trough in a perspective view,

FIG. 2

in the Fig. 1 shown multi-level trough in a cross-sectional view,

FIG. 3

in the Fig. 1 and 2 shown multi-level trough in a perspective view in connection with a connection to the sewer,

FIG. 4

another multi-level trough in a perspective view and

FIG. 5

in the Fig. 4 shown multi-level trough in a cross-sectional view.

Fig. 1 shows a multi-deck trough 1 comprising an upper drainage cross-section 2 and a lower drainage cross section 3. The drainage sections 2 and 3 each consist of two spaced gutter walls 4, 4 ', which are each connected to each other by a common trough sole 5. On the top side, the channel walls 4, 4 'are each closed by a frame 6, 6'. In the frame 6 of the upper drainage cross section 2, a gutter cover not shown here is usually inserted, which is flush in the installation position with the surface to be drained.

On the frame 6, 6 'of the lower drainage cross section 3 sits the trough 5 of the upper drainage cross section 2 under cross plane footprint 7, wherein the footing 7 is widened on both sides arranged side webs 8, 8' such that the through the side webs 8, 8 Broadened plane footprint 7 of the upper drainage cross section 2 is positively received in the frame 6, 6 'of the lower drainage cross section 3.

Like also out Fig. 1 can be seen, the two drainage sections 2 and 3 are each provided with an external ribbing 9 for additional stiffening of the channel cross-sections. In this case, the outer ribbing 9 is connected to the side webs 8, 8 'arranged on both sides, so that thereby also a additional stiffening of the outer ribbing 9 and thus also the drainage sections 2 and 3 is achieved in total.

Fig. 2 shows the in Fig. 1 shown multi-level trough 1 in a cross-sectional view, in particular, the connection between the upper drainage section 2 and the lower drainage cross section 3 is visible in this view. In this embodiment, the entire region of the trough sole 5 is sealed at least in the illustrated section by means of a closure flap 10, wherein the closure flap 10 is articulated in the region of the trough sole 5 via a resilient hinge joint 11 in the transition region between the channel wall 4, 4 '. The spring constant of the hinge joint 11 is set so that the hinge joint 11 opens when exceeding a defined hydraulic pressure, ie a defined amount of incoming and not discharged water, and in the event that the inflowing water is less and thus the hydraulic pressure decreases, the flap automatically closes again as a result of the return spring of the hinge joint 11. As can also be seen in particular from this cross-sectional illustration, the side bars 8, 8 'accommodated on both sides in the frame 6, 6' can, if necessary, be detachably or irreversibly connected to the frame 6, 6 'of the respectively lower drainage cross-section 3 using suitable connecting means, such as rivets or screws get connected.

Fig. 3 shows in a perspective view the connection of in Fig. 1 and 2 According to this illustration, the multi-deck trough 1 is connected via a common inlet connection 13 with the gully 12, within which not shown here, preferably with the interposition of suitable filtration and sedimentation for the pre-cleaning of the introduced surface water, the Surface water is discharged down into a deeper drains, which is connected via the outlet connection 14, 14 'to the gully 12.

In an alternative embodiment according to the perspective view in Fig. 4 can the multi-level trough 1 also multi-storey, in the present embodiment, three-storey, be formed. In this case, the structural design and in particular the connection of the individual drainage cross sections 2, 3 and 15 does not differ from the multi-level trough 1 according to Fig. 1 and 3 , so that further statements in this context seem dispensable.

The nominal diameters of the drainage cross sections 2, 3 and 15 extend from top to bottom, as shown in the cross sectional view in FIG Fig. 5 is apparent. The nominal widths are dimensioned so that at least when disassembled side bars 8, 8 ', the individual drainage sections 2, 3 and 15 are stackable, so that a reduced transport and storage volume of multi-deck trough 1 can result.

In any case, illustrate the above embodiments that the multi-deck trough 1 with more or less undiminished nominal size of the required only for the upper drainage section 2 gutter cover has a significantly increased by the additional drainage sections 3 and 15 absorption capacity.

LIST OF REFERENCE NUMBERS

1

Multi-level channel

2

Upper drainage cross section

3

lower drainage cross section

4, 4 '

Rinnenwandungen

5

channel base

6, 6 '

frame

7

footprint

8, 8 '

sidebars

9

outer ribbing

10

flap

11

hinge

12

gully

13

flowguide

14, 14 '

outlet connection

15

lowest drainage cross section

Claims (9)

Drainage channel for drainage of surfaces, in particular of traffic areas,
characterized in that the drainage channel is designed as a multi-level trough (1) such that a first Entwässerungsquerschnitt (2) comprising two spaced gutter walls (4, 4 '), which are overlapped on the upper side of a gutter cover and the underside through the trough sole (5) with each other are connected, wherein the trough sole (5) in turn is attacked by a flat footprint (7), is undercut by at least one further drainage cross section (3) such that the respective upper drainage cross section (2) with the respective lower drainage cross section (3) over at least an opening in the respectively between the two drainage cross sections (2, 3) arranged trough sole (5) is connected. Drainage channel according to Claim 1, characterized in that, when the multi-level trough (1) is constructed as intended, the sole region terminating in the upper horizontal drainage cross-section (2) is engaged by an at least largely planar footprint (7) which at least indirectly engages on the frame ( 6, 6 ') of the lower side subsequent, each lower drainage cross section (3) is seated. Drainage channel according to claim 1, characterized in that the installation surface (7) of the respective upper drainage cross section (2) is extended by means of side webs (8, 8 ') arranged on both sides, wherein the side webs (8, 8') on the frame (6, 6 ') of the respective lower drainage cross-section (3) are mounted in the installation position. Drainage channel according to claim 2 or 3, characterized in that the side bars (8, 8 ') arranged on both sides of the upper drainage cross section (2) in the installed position are fastened to the frame (6, 6') of the frame by means of suitable connecting means, preferably rivets or screws are each connected in the installation position lower drainage cross-section (3). Drainage channel according to one or more of the preceding claims, characterized in that the opening, openings in the sole region of the upper drainage cross-section (3) of the multi-level trough (1) in each case in the installation position are provided with a closure, which, in consequence of automatically opens, opens and closes automatically when the pressure drops below this defined pressure level. Drainage channel according to claim 5, characterized in that the closure or closures are each spring-operated closing flaps (10). Drainage channel according to one or more of the preceding claims, characterized in that the nominal widths of the drainage cross sections (2, 3, 15) of the multi-level trough (1) arranged one above the other in the installed position expand from top to bottom. Drainage channel according to claim 7, characterized in that the nominal widths of the drainage cross sections (2, 3, 15) to be arranged one above the other in the installed position are dimensioned such that the drainage cross sections (2, 3, 15) are at least disassembled side bars (8, 8 '), preferably for the purpose of storage and / or transport, are stackable. Drainage channel according to one or more of the preceding claims, characterized in that the multi-level trough (1) is completely or at least predominantly made of plastic.

Images