DE20303259U1 - Rain water cistern has overflow control by closing inlet - Google Patents

Abstract

A rain water cistern (2) has a water level (10) sensor (9) and control valve (6) that diverts the water from the rain water inlet pipe (3) direct to a drain (8). Includes an INDEPENDENT CLAIM for a float valve closing the inlet pipe within the tank.

Description

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Rainwater cistern with liquid level regulation

The invention relates to a rainwater cistern into which a downpipe, optionally containing a filter, opens, wherein a regulating device regulating the outflow into a sewer prevents the liquid level from exceeding a predetermined value.
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Such rainwater cisterns, from which the collected and filtered rainwater can be taken for use in the house (toilet flushing, washing machine), for example, are usually designed in such a way that the overflow of the cistern is connected to the local sewer by means of a siphon.

According to the new version of DIN 1989 (rainwater utilization systems), it is prescribed that rainwater storage tanks must be protected against backflow, although a connection via a backflow valve is not permitted. The backflow level is generally the upper edge of the manhole cover of the house connection. For underground cisterns, this means that a direct connection of the overflow to the sewer is no longer possible. In this case, a lifting device must be used, but this makes rainwater utilization almost unaffordable due to the resulting costs.

The invention is therefore based on the object of designing a rainwater cistern of the type mentioned at the beginning in such a way that liquid level regulation is possible in a simple manner without a backflow valve and without a lifting mechanism.

To solve this problem, the invention provides that the regulating device interrupts the water supply to the cistern and diverts the rainwater directly into the sewer.

This approach, which is completely different from the previous state of the art, to avoid an excessive level of liquid in the rainwater cistern can be achieved very easily according to a first embodiment of the invention by arranging a switch controlled by a level sensor in the rainwater downpipe to a connecting line to the sewer. As soon as the level of liquid in the rainwater cistern has reached a predetermined value, the level sensor is activated and prevents further rainwater from entering the cistern via the switch. Instead, the rainwater is then fed directly into the sewer until the level of liquid in the cistern drops accordingly.

It is possible to have an electrical sensor control an electromechanical switch, or to use a purely mechanical sensor and a matching mechanical switch.

According to a second embodiment of the present invention, a level-dependent shut-off device is arranged in the downpipe below the branch of a connecting line to the sewer. As soon as the liquid level in the cistern exceeds a certain level, the shut-off device is activated, whereupon the rainwater is dammed up in the downpipe and finally flows directly into the sewer at the branch already mentioned via a connecting line.

In a further development of the invention, it can be provided that the level-dependent shut-off device comprises a float.

Such a float can be arranged in an extended outlet chamber of the downpipe and thus directly form a shut-off ball for the downward-facing outlet opening of the downpipe.
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Alternatively, the float may be mounted at the end of a pivoting lever which carries a shut-off device for the outlet opening of the downpipe.

A first variant of this design provides that the lever is a two-armed lever with a shut-off device at the free second end of the lever for an upwardly directed outlet opening of the rainwater downpipe.
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In a second variant, the lever is a one-armed lever with a shut-off device arranged between the pivot bearing and the float for a downward-facing outlet opening of the downpipe.

The lever arms are dimensioned in such a way that the buoyancy of the float in conjunction with the lever arm ratio ensures that the rainwater accumulating in the downpipe up to the branch of the connecting line to the sewer cannot push the shut-off device into the open position.

Further advantages, features and details of the invention emerge from the following description of some embodiments and from the drawing. In the drawing:

Fig. 1 is a schematic representation of an underground rainwater

terne with a switch in the downpipe,

Fig. 2 shows an embodiment of a rainwater cistern according to the invention, in which the inflow of rainwater to the cistern is regulated by a level-dependent shut-off device and

Fig. 3 to 5: Examples of the shut-off device for the construction according to Fig. 2.

A rainwater downpipe 3 opens into the rainwater cistern 2 sunk into the ground 1, which could also, if necessary, be drawn downwards, as indicated by the dashed line, and provided with an upwardly directed outlet opening.

Above the backflow level 4, a switch 6 is switched on in the downpipe 3, which could possibly also contain a filter 5 above it. When activated, this switch no longer allows the rainwater to flow further down the downpipe 3, but instead directs it via a branching connecting line 7 directly into the sewer 8. The switch is activated via a sensor 9, which is arranged at the desired maximum height of the liquid level 10. As soon as the liquid level has reached this value and thus causes the sensor to respond, the switch 6 is switched so that the rainwater in the downpipe only flows into the connecting line 7 to the sewer 8.

The embodiment of a rainwater cistern according to Fig. 2 differs from that according to Fig. 1 in that instead of a sensor with a switch in the rainwater downpipe, a level-dependent shut-off device 11 is provided, which in the embodiment shown is arranged near the outlet of the rainwater downpipe 3. As soon as the shut-off device closes due to the actuation of the level-dependent shut-off device with a corresponding increase in the liquid level 10, the rainwater accumulates in the rainwater downpipe 3 up to the junction 12, where the connecting line to the sewer 8 branches off. From this point on, the rainwater is then only directed directly into the sewer, so that a further increase in the liquid level 10 in the rainwater cistern 2 can no longer occur.

Fig. 3, 4 and 5 show different embodiments of a level-dependent shut-off device 11. In the embodiment according to Fig. 3, an extended outlet chamber 14 is connected to the end of the downpipe 3 with a downward-facing outlet opening 13, in which there is a float 15 which simultaneously forms the shut-off ball for the outlet opening 13. If the level 10 of the rainwater in the cistern rises, this is pressed against the outlet opening 13, with the cross-sections being selected such that the buoyancy of the ball is sufficient to absorb the weight of the water column up to the branch 12.

Fig. 4 and 5 also show level-dependent shut-off devices 11 provided with a float 15'. The float 15' is arranged at one end of a lever arm 16, which is pivotally mounted at 17. In the embodiment according to Fig. 4, the lever arm 16 carries a sealing plate 18 and in the embodiment according to Fig. 5, a sealing slide 19 as a shut-off device for the downpipe 3.

The invention is not limited to the embodiments shown. In particular, it would also be possible to design the lever 16 as a two-armed lever, with the sealing element being arranged at the free end of the lever remote from the float. Such a level-dependent shut-off element would be suitable for shutting off a rainwater downpipe, as indicated by dashed lines in Fig. 1 and 2, which therefore has an outlet opening pointing upwards. The house wall is indicated at 20.

-Protection claims-

List of reference symbols

1 Floor 2 Rainwater cistern 3 Rain downpipe 4 Backflow level 5 filter 6 Switch 7 Connecting line 8th sewer 9 sensor 10 Liquid level 11 Shut-off device 12 Junction 13 Outlet opening 14 Outlet chamber 15, 15' swimmer 16 Lever arm 17 Pivoting bearing 18 Sealing plate 19 Sealing slide

Rehau, 26.02.2003 dr.schi-zh

Claims (10)

1. Rainwater cistern into which a downpipe, optionally containing a filter, opens, wherein a regulating device regulating the outflow into a sewer prevents the liquid level from exceeding a predetermined value, characterized in that the regulating device interrupts the water supply to the cistern ( 2 ) and diverts the rainwater directly into the sewer ( 8 ). 2. Rainwater cistern according to claim 1, characterized in that a changeover switch ( 6 ) controlled by a level sensor ( 9 ) to a connecting line ( 7 ) to the sewer ( 8 ) is arranged in the downpipe ( 3 ). 3. Rainwater cistern according to claim 2, characterized in that an electrical sensor controls an electromechanical switch. 4. Rainwater cistern according to claim 2, characterized in that a mechanical sensor and a mechanical switch are provided. 5. Rainwater cistern according to claim 1, characterized in that a level-dependent shut-off device ( 11 ) is arranged in the downpipe ( 3 ) below the branch ( 12 ) of a connecting line ( 7 ) to the sewer ( 8 ). 6. Rainwater cistern according to claim 5, characterized in that the level-dependent shut-off device ( 11 ) comprises a float ( 15 , 15 '). 7. Rainwater cistern according to claim 6, characterized in that the float ( 15 ) arranged in an enlarged outlet chamber ( 14 ) of the downpipe ( 3 ) forms a shut-off ball for the downwardly directed outlet opening ( 13 ) of the downpipe ( 3 ). 8. Rainwater cistern according to claim 6, characterized in that the float ( 15 ') is attached to the end of a pivotably mounted lever ( 16 ) which carries a shut-off device ( 18 , 19 ) for the outlet opening ( 13 ) of the downpipe ( 3 ). 9. Rainwater cistern according to claim 8, characterized in that the lever is a two-armed lever with a shut-off device at the free second lever end for an upwardly directed outlet opening of the rainwater downpipe. 10. Rainwater cistern according to claim 8, characterized in that the lever ( 16 ) is a one-armed lever with a shut-off device ( 18 , 19 ) arranged between the pivot bearing ( 17 ) and the float ( 15 ') for a downwardly directed outlet opening ( 13 ) of the downpipe ( 3 ).