DE29513881U1 - Overflow structure in a rainwater discharge system for mixed sewage systems - Google Patents

Description

PASSAVANT-WERKE AG
65322 Aarbergen 7

Overflow structure in a stormwater discharge system for combined sewerage

The innovation concerns an overflow structure in a stormwater discharge system for the combined sewer system.

In a combined sewer system in which rainwater and municipal wastewater are drained together, most of the resulting mixed water is discharged into the receiving waters via the relief system provided during heavy rain. The relief system normally consists of an overflow sill that divides the supply channel to the side, on which a catch grate that can be pivoted about a horizontal axis is mounted. The catch grate consists of a large number of grate bars arranged at a gap distance. A lower stop holds the grate bars in the rest position horizontally facing the inlet side (DE-OS-40 15 414).

When heavy rain sets in, the pollutants deposited in the sewerage system of the catchment area are washed away and reach the overflow structure, where the level rises quickly on the inflow side. The catch grate comes into operation when the overflow threshold is reached and intentionally catches the coarse pollutants brought in by the mixed water.

back, so that essentially only mechanically cleaned water flows over. As soon as the rake is clogged with dirt and the flow resistance has increased, the rake is raised. The upward swing is limited by an upper stop. In this position, the rake is only overflowed and can no longer hold back coarse material. After the heavy rain has subsided, the level in front of the overflow threshold drops and the rake returns to the rest position.

With regard to the whereabouts of the pollutants held back by the rake, this type of rake is unsatisfactory. The rake still holds onto the pollutants after returning to its rest position. It is not reasonable to expect sewage treatment plant staff to inspect the relief structure, which is usually installed far away from the sewage treatment plant, after every heavy rain and to clean the rake. The task therefore arises of improving the rake installed in a relief structure so that it is automatically freed of the pollutants after every heavy rain. This task is solved in accordance with the innovation by a cleaning rake that engages in the rake from above, can be pivoted about the same horizontal axis and has a float that responds to the water level on the inlet side, which raises the cleaning rake before it reaches the overflow threshold. The rake then returns to its rest position, which is secured by the lower stop, earlier. The cleaning rake, which is operated by its float, then also falls back into the horizontal resting position and scrapes the contaminants out of the rake gaps so that they fall into the channel and are washed away with the water.

The new overflow structure can be designed in such a way that the shaft of the catcher is designed as a solid shaft and the shaft of the cleaning rake is designed as a hollow shaft that concentrically surrounds the solid shaft at a distance. Where the rods of the catcher pass through the hollow shaft to the outside, the hollow shaft has recesses that extend over the circumference to a corresponding length, which allow the catcher to pivot fully relative to the cleaning rake. In order to prevent contaminants from entering the interior of the hollow shaft through these recesses, a further development of the innovation is provided, a second hollow shaft that concentrically surrounds the first hollow shaft at a small distance and extends in the circumferential direction as far as

extends so that it covers the recesses of the first hollow shaft in every relative position. This second hollow shaft, which acts like a cover, can also consist of individual curved sections, each of which is placed over a bar of the catch rake.

The innovation is explained in more detail below using a preferred embodiment, which is shown in the drawing. They show:

Fig.l shows a schematic section through a

Relief structure equipped with a weir, Fig.2 a detail of Fig.l with two intermediate positions of the two

rake,
Fig.3 a cross-sectional view of the two rakes

waves, and
Fig.4 the shaft arrangement according to Fig.3 in longitudinal section.

The left channel wall 1, the channel floor 2 and the overflow wall 3 that divides the channel lengthwise can be seen from the stormwater relief structure that is installed in the inlet to the sewage treatment plant and the stormwater collection basin. The mixed water, which normally only reaches the level 4, flows through the structure without resistance.

Two rakes 6, 7 are arranged on the top of the overflow wall 3 and can be pivoted around the same axis 5. The first, shorter rake 6 is the catch rake, the second is the cleaning rake 7. Both rakes have floats 8, 9, with the float 9 of the cleaning rake 7 being attached to a downwardly projecting cantilever arm 10. Both floats 8, 9 are assigned a lower stop 11, 12 in which they are in the rest or starting position. There is a common upper stop 13 for both rakes, which determines the end position that must not be exceeded. The position is slightly off the vertical line so that both rakes can automatically return to the rest position after the jam has subsided.

In Fig.2 two intermediate positions of the two rakes are shown. Due to the float 9 arranged on a cantilever arm 10, the cleaning rake 7 already lifts off at the level 4 shown in Fig.1. As soon as the level

4' has reached the mark shown in Fig.2, the catch screen 6' also comes into operation, i.e. it is raised and then flowed through (arrow 14). The cleaning screen behind it, which does not need to hold back any contaminants, is also flowed through in the area close to the wave. As the catch screen becomes increasingly clogged, the flow resistance increases and the catch screen 6" is swiveled up further. As the level 4" on the inflow side continues to rise, the cleaning screen 7" is also raised further. In the end position at the upper stop 13, only the cleaning screen in the outer section protruding above the catch screen is flowed through.

When the inlet-side dam drains, the catcher begins to sink to the left. This is followed later by the cleaning rake. The catcher is also the first to return to the starting position determined by the lower stop 12. The cleaning rake then falls in from behind and scrapes the dirt out of the gaps in the catcher so that it can be washed away with the mixed water. The catcher is automatically cleaned for the next use. As Fig. 2 clearly shows, the cantilever arm 10 for the float 9 of the cleaning rake 7 is bent so far to the right that both floats are close to each other and then operate the two rakes in the desired manner.

The structural implementation of the innovation is shown in Figures 3 and 4. The shaft 15 for the catch rake 6, which is composed of a large number of flat bars 16, is a solid shaft that is mounted in axle bearings 17. The rake bars are spaced apart by spacers 18.

The bars 19 of the cleaning rake 7, which are also made of flat steel, are butt-mounted on the shaft 20, which is designed as a hollow shaft. The hollow shaft is closed at both ends with a passage opening for the solid shaft 15. The hollow shaft is supported in bearings 21 arranged next to the bearings 17.

The hollow shaft 20 has, where it is penetrated by the bars of the catch rake, curved recesses 22 extending over part of the circumference. The areas of the curved recesses that are not covered by the flat

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The openings occupied by the bars of the catch screen are open on the inlet side. A second hollow shaft 23, which is penetrated by the flat bars of the catch screen and is permanently connected to them, acts as a cover that prevents dirt from entering the interior of the hollow shaft. A separate bearing for this second hollow shaft 23 is not necessary because it is connected to the catch screen and thus to its shaft. The diameters of the two hollow shafts are matched to one another in such a way that the overlapping sections are sufficiently sealed. The second hollow shaft can also be broken down into individual curved sections that are of such a width and arc length that they seal the recesses 22 in the first hollow shaft 20 in any relative position of the two screens.

Claims (7)

G 1735 Claims 1. Overflow structure in a rainwater relief system for combined sewage systems, with an overflow sill (3) laterally dividing the supply channel, on which a catch grate (6) for floating matter is mounted, which can be pivoted about a horizontal axis (5) and consists of vertical bars, the rest position of which is the horizontal position directed towards the inlet side, secured by a stop (8), characterized in that the catch grate (6) is assigned a cleaning grate (7) which engages it from above, which can be pivoted about the same horizontal axis (5) and contains a float (9) which reacts to the water level on the inlet side and is at such a height that the cleaning grate (7) is pivoted up before the catch grate is reached by the level of the rainwater. 2. Overflow structure according to claim 1, characterized in that the catch grate (6) is also assigned a float (8) which causes it to swing upwards when the water level on the inlet side rises. 3. Overflow structure according to claim 1 or 2, characterized in that the lower stops (11, 12) for the rest positions are assigned to the floats (8, 9). 4. Overflow structure according to claim 1, 2 or 3, characterized in that the cleaning rake (7) exceeds the catch rake (6) in horizontal length and that the overshooting section of the cleaning rake (7) is designed as a catch rake. 5. Overflow structure according to claim 2 to 4, characterized in that the float (9) of the cleaning rake (7) is arranged on a larger radius than the float (8) of the catching rake (6) so that it can move past the other float (8). 6. Overflow structure according to one or more of claims 1 to 5, characterized in that the shaft (15) of the catcher (6) is designed as a solid shaft and the shaft (20) of the cleaning rake (7) is designed as a hollow shaft concentrically surrounding the solid shaft at a distance, and that the hollow shaft (20) has cutouts (22) of such a circumferential extent where the rods (16) of the catcher (6) penetrate the hollow shaft (20) that the rods (16) of the catcher can carry out the full pivoting movement. 7. Overflow structure according to claim 6, characterized in that a second hollow shaft (23) is attached to the bars (16) of the catch grate (6), which second hollow shaft (23) concentrically surrounds the first hollow shaft (20) without a significant gap and is drawn around the first hollow shaft (20) at least so far that the open sections of the cutouts (22) of the first hollow shaft (20) are covered in every position of the shafts relative to one another.