DE9108904U1 - Device for rinsing the screen in a storm overflow basin and for cleaning the basin - Google Patents

Description

Device for rinsing the screen in a storm overflow basin and for cleaning the basin

The subject of the present invention is a device for flushing the screen in a storm overflow basin and for cleaning the basin according to the preamble of claim 1.

When it rains, especially when it is torrential, the water flowing into the sewage treatment plants cannot be fully absorbed by the stormwater basins for cleaning. A portion of this large amount of rainwater must therefore be fed into a stormwater overflow basin, in which coarse particles such as leaves, branches and other solids carried along with it are sifted out before the water is discharged untreated into a receiving water or a flowing body of water. It is known that the water flowing out of the stormwater basins is usually led from bottom to top through a horizontal rake or through a horizontal sieve, a perforated plate or another type of filter before it is discharged into a channel that runs past the stormwater basin.

The amount of rubbish carried along during heavy rainfall can clog the rake in a short time, so that no or not all of the water can pass through the rake. It is therefore necessary that from time to time, during the rain event if necessary, the impurities adhering to the underside of the rake are removed. This can be done either mechanically or by spraying the rake from above, if the rain basin has previously been at least partially emptied and the underside of the rake has thus been exposed. Cleaning can also be carried out using a flushing tip arranged above the rake.

In addition to the rake, the rain basin itself must also be cleaned of any dirt that has settled in it after a major rainfall event. This can be done with a flushing bucket or, more laboriously, with a hose.

The object of the present invention is to create a device with which the rake can be cleaned in a simple manner.

This object is achieved by a device as specified in the characterizing features of claim I.

The water column built up above the screen and maintained after the rain event has ended allows a powerful water surge to be generated after the rain basin has been emptied, which simultaneously cleans the screen and the bottom of the rain basin. The water column built up above the screen has the particular advantage that it flows through the entire cross-section of the screen at the same time, so that contaminants adhering to the underside of the screen cannot escape to the side, but are carried downwards as a whole. The water surge that passes through the screen and carries the contaminants with it after passing through enters the rain basin in a concentrated form at the lower edge of the partition wall as a high-energy water surge and washes the contaminants lying on the brine to the drainage channel, from which they can be fed to the sewage treatment plant. Since the water column above the screen has previously been freed of the coarse debris by the screen, no particles that could clog the screen reach its surface. Contaminants cannot clog the top of the screen either, if so much water flows into the stormwater basin that the screen cross-section can no longer absorb it and the completely uncleaned water is therefore led via the chamber with the screen directly to the discharge channel. When using a cover bridging the chamber with the screen, a floating baffle can be used to keep the contaminants away from the partition wall.

The invention is explained in more detail using an illustrated embodiment. Shown are:

Figure 1 shows a cross-section through a stormwater basin with a laterally arranged relief channel,

Figure 2 shows a partial cross-section through a stormwater overflow basin with a relief channel running inside the basin,

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Figure 3 shows another cross-section through a storm overflow basin, Figures 4 and 5 show a floor plan of an emergency overflow in a storm basin system and
Figure 6 shows a floor plan of a storm water basin system.

In the following, the term "rake" is understood to mean any type of device that can be used to filter out impurities present in the water. For this purpose, rakes made of rods, sieves made of wire mesh or perforated metal sheets, or filters made of fibers or wires, for example, can be used.

The rain basin structure 1 shown in cross-section in Figure 1 has side walls 3, 5, 7 and the wall in front of the section that is not visible and a ceiling 9 that covers the basin, which is usually below the natural terrain, and makes it navigable if necessary. A relief channel 11 runs parallel to the side wall 5 and leads via a pipe 13 to a receiving water body or an inland or flowing body of water. In the example according to Figure 1, the relief channel 11 is part of the structure 1 and is formed from the wall 5, which does not reach up to the ceiling 9, and a channel wall 15. The rain basin 1 can also be designed as a channel.

The floor 17 of the rain basin 1 and the wall 5 are connected seamlessly to one another by an arched or inclined connecting surface 19. In the area of the wall 3, the floor 17 preferably has a collecting channel 21, which is connected to a drain line 23 that breaks through the wall 7 and leads to the sewage treatment plant. A partition wall 25 is inserted at a distance from the side wall 5, the lower edge 27 of which ends at a distance from the brine or floor 17. The upper edge 29 of the partition wall 25 also ends at a distance from the ceiling 9. Starting at the upper edge 29, a cover plate or bridge 31 extends in the direction of the overflow channel 11 and ends above the latter. The cover plate 31 spans the chamber formed by the side wall 5 and the partition wall 25, located inside the basin 1. The cross section of the chamber 33 is completely spanned by a rake or sieve 35. The rake 35 can consist of vertically positioned flat iron profiles or be designed as a perforated sheet and is anchored in the side wall 5 or the partition wall 25. The partition wall 25 can

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essentially parallel to the side wall 5. The chamber 33 can also be expanded above the rake 35 to increase the volume (indicated in dotted lines).

The slot-shaped opening 37 formed between the lower edge 27 of the partition wall 25 and the floor 17 can be closed on the rain basin side by a closing flap 39. The flap 39 can be lifted off the opening 37 using a mechanism not described in detail or a pneumatic, hydraulic or electric drive. The flap 39 can be triggered by a time relay or by a vacuum or float control, whereby the trigger sensor can be arranged elsewhere in the basin 1.

In the embodiment of the invention according to Figure 2, the chamber 33 is divided into two sections in the area above the screen 35 by an intermediate wall 41, whereby only one of the two sections, namely the one that is closer to the overflow channel 11, is spanned by the screen 35. In the area of the upper edge 29 of the partition wall 25, a floating baffle 43 is arranged that is pivotably attached to the ceiling 9, as is described, for example, in Swiss patent specification 634371. In addition to the baffle 43 or instead of it, a cover plate 31 can also be attached to the intermediate wall 25, which spans the chamber 33.

In the embodiment of the invention according to Figure 3, the overflow channel 13 is not located on the side of the basin 1, but rather it passes through it. The overflow channel 11 is formed on the one hand by the partition wall 25 and on the other hand by the intermediate wall 41, which divides the chamber 33 into two sections in the upper part as in Figure 2. In this embodiment, neither a cover 31 nor a baffle wall 43 is necessary, as will be explained later.

The functionality of the devices is explained in more detail below. Contaminated water enters the rain basin 1 through an inlet opening 45 and leaves it if the inflowing quantity is smaller than the quantity that can be fed to a sewage treatment plant through the outlet pipe 23. If the inflowing quantity of water is larger than the maximum possible outflow, the rain basin 1 gradually fills up. The mechanism (not further described) separates the flap 39 from the opening 37.

kept raised so that the water accumulating in the rain basin 1 can be distributed and rise on both sides of the partition wall 25, i.e. in the basin 1 and in the chamber 33. As soon as the level H1 of the screen 35 is reached and the water level continues to rise, the portion of the water in the chamber 33 that passes through the screen 35 from bottom to top is sieved and any impurities floating on the surface are retained under the screen 35. If the water continues to rise and reaches the level H2 of the upper edge 6 of the wall 5, the water cleaned by the screen 35 can be drained into the overflow channel 11 and from there through the drain channel 13 into a receiving water body.

If the water level continues to rise as a result of a large inflow into the storm water basin 1 despite overflow in the overflow channel 11 and the water level reaches the level H3, the water can flow directly and uncleaned into the drainage channel 13 via the upper edge 29 or the cover plate or bridge 31. The cover plate 31 prevents the top of the grate 35 from becoming dirty.

However, with average rainfall, sieve 35 ensures that all water that does not flow into the sewage treatment plant is cleaned.

In the embodiment according to Figure 2, the cleaning of the water that does not reach the sewage treatment plant via the drain line 23 is analogous to that in Figure 1. However, as soon as all of the inflowing water can no longer be directed through the rake 35 to the overflow channel 11, the water can be directed directly to the overflow channel 11 via the upper edge 40 of the partition wall 41 at the height H4. In this case, floating impurities that have passed through the opening 37 on the lower edge 27 of the partition wall 25 are held back by a grid 26. Only water that is contaminated with floating, coarser impurities can thus pass between the partition wall 25 and the partition wall 41 to the overflow channel 11. If the water continues to rise, the impurities floating on the surface in the basin 1 can be prevented from crossing the partition wall 25 into the chamber 33 by means of a floating baffle 43, so that the impurities floating on top cannot reach the overflow channel 11 in any case. A cover plate 31 directs the water separated from the floating impurities directly to the overflow channel 11.

In the embodiment of the invention according to Figure 3, in which the overflow channel 11 is located within the rain basin 1, the conditions are the same as in the embodiment according to Figure 1. A cover plate 31 above the rake 35 is not necessary in this embodiment. It is also possible to use a floating baffle 43 on the partition wall 25, analogous to the embodiment in Figure 2, in order to avoid contamination of the top of the rake 35.

Depending on the design of the rake 35, fine-meshed or coarse-meshed, the height Hl at which it is arranged can vary. A smaller water column is sufficient for cleaning a coarse-meshed rake 35 than for a fine-meshed one. If the device is only used for cleaning the rake 35, it is of course installed at the lowest possible point.

Of course, the rake can also be installed at an angle or vertically. The cleaning effect of the water column above the rake is retained.

As soon as the inflow of contaminated water through the inflow opening 45 decreases to such an extent that the water level in the basin 1 begins to sink, the flap 39 is pivoted downwards in front of the opening 37 by the mechanism (not shown and illustrated) and keeps it closed. As the water level in the basin 1 continues to sink, the water column in the chamber 33 remains. As soon as the basin 1 has been completely emptied through the drain line 23 or a pump, the flap 39 is suddenly opened manually or automatically. The chamber 33 is emptied through the now exposed slit-shaped opening 37. The water flowing rapidly downwards has two effects. Firstly, the water held back above the grate 35, which has already been cleaned by it, loosens the contaminants adhering to the underside of the grate 35 and carries them away. The water surge from the chamber 33, which flows at high speed through the opening 37 along the bottom 19 of the basin, simultaneously loosens the substances deposited on the bottom 17 of the basin and transports them to the collecting channel 21, from where they are fed directly to the sewage treatment plant. The rain basin 1 and the screen 35 are then cleaned and ready for the next rainfall event.
In order to also clean the pelvic floor 17,

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If there was not such a large amount of water previously and therefore the chamber 33 was not filled with water, an additional water supply line 49 of fresh or service water can be introduced into the chamber 33. By closing the flap 39, the chamber 33 can be artificially filled and the water can then be drained off as a surge.

The devices described above using cross-sections can be used in systems of different designs.

Figures 4 to 6 show three possible designs of storm basins or emergency overflow systems. In the embodiment of the invention according to Figure 4, the chamber 33 is located to the side of the basin 1, which is designed as a storage channel. A slide valve 22, e.g. a throttle valve, is installed in front of the discharge line 23, with which the amount of water fed to the wastewater treatment plant can be adjusted. The storage channel is cleaned by opening the flap 39 under the partition wall 25.

In Figure 5, the chamber 33 is arranged at the front of the storage channel 1, so that the water surge flows directly into the storage channel 1. Figure 6 shows three basins 1 separated from one another by walls 2, each with an associated chamber 33 with a rake 35. The three basins 1 are connected to a common sump 21. The capacity of the sump 21 only has to be designed for the volume of one of the chambers 33, since the individual basins can be flushed one after the other.

The rake and pool cleaning devices described in Figures 1 to 6 can of course be installed not only in rectangular pools and channels, but also in round pools and in two-tier pools.

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Claims (10)

üisprüche 1. Device for flushing the screen in a storm overflow basin and for cleaning the basin with a flood overflow into a relief channel, characterized in that the rake (35) is inserted in a chamber (33) arranged to the side of the relief channel (11) and formed by a partition wall (25), which partition wall (25) has a gap-shaped opening (37) with a closure flap (39) on its lower edge (27) and a passage to the relief channel (11) on its upper edge (29). 2. Device according to claim 1, characterized in that the upper edge (29) of the partition wall (25) is at a distance from the ceiling (9) of the building (1). 3. Device according to one of claims 1 or 2, characterized in that the partition wall (25) is parallel to the side wall (5) of the basin (1), the rake (35) being inserted between the side wall (5) and the partition wall (25). 4. Device according to claim 3, characterized in that above the a cover plate or bridge (31) connected to the upper edge (29) of the partition wall (25) is arranged in the chamber (33) formed by the side wall (5) and the partition wall (25), the edge of which facing away from the partition wall (25) lies above the relief channel (11). 5. Device according to one of claims 3 or 4, characterized in that an intermediate wall (41) is arranged between the side wall (5) and the partition wall (25), between which (41) and the side wall (5) the rake (35) is inserted. 6. Device according to claim 5, characterized in that the upper edge (40) of the intermediate wall (41) is higher than the overflow edge to the relief channel (11) and lower than the upper edge (29) of the partition wall (25). 904. 7. Device according to one of claims 5 or 6, characterized in that the overflow channel (11) is located between the partition wall (25) and the intermediate wall (41) and the rake (35) is inserted between the intermediate wall (41) and the side wall (5). 8. Device according to one of claims 1 to 7, characterized in that the floor (19) below the rake (35) is curved and/or inclined. 9. Device according to one of claims 1 to 8, characterized in that a floating baffle (43) is arranged in the region of the upper edge (29) of the partition wall (25) on the pool side. 10. Device according to one of claims 1 to 9, characterized in that the basin (1) and the chamber (33) are divided into sections by walls (2), each section being assigned a flap (39) which can be lifted off the opening (37) independently of the adjacent sections, and in that the sections have a common sump (21).