DE4240057A1 - Installation for collection of water-pollutant liqs from roadway - Google Patents

Abstract

The installation allows surface water to be drained (2) into a pipe (3) leading into a reinforced concrete sediment trap (4) with liq. sensors (11, 12) in an overflow section (8) and on the floor.When a tanker vehicle is positioned on the surface (1) a motor-driven blocking valve (10) in the pipe is closed so that split oil is accumulated in the overflow section. At the level of the sensor (11) a signal is sent to a control unit (13) giving a visual or audible alarm.

Description

The invention relates to systems for filling and handling of water-polluting liquids on squares under open sky.

Such places that are used by tanker trucks are, because they are sealed against the underground, for draining the rainwater. The processes are accordingly connected to the sewage system.

In the event of an accident, i. H. in the event of an unforeseen escape transhipped liquid, these liquids must be removed from the sewage system. There is for that already catch basin from one in the pipeline  activated shut-off device via an integrated Overflow opening are applied (DE-GM 86 00 827). A Sensor in front of the shut-off device senses the amount of fluid and blocks the process in no time.

This facility is not yet on the operating conditions coordinated at the handling center. The sensor cannot between rainwater and dangerous liquid distinguish and therefore also closes in rainwater. In addition, at the moment when the dangerous Liquid triggers the sensor and the shut-off device closes, a certain amount of liquid that Shut-off device happens via sewerage. The task of this Avoiding malfunction is already a new one System has been solved in which the shut-off device is no longer through a liquid sensor but from the one on the Transshipment point arrived and connected tanker truck is closed (DE-OS 38 22 107). The shut-off device is So already closed if due to an accident dangerous liquid runs into the drain. The Liquid is stored in the collecting basin and can to be disposed of later.

Another improvement to this system is to provide a liquid sensor in front of the shut-off device, which is connected to the shut-off device such that the Shut-off device in the presence of liquid before Shut-off device cannot be opened (DE-OS 38 22 107). The dangerous liquid must therefore be completely exhausted be removed from the pipeline before, after the end of  Decanting, the shut-off valve opened again for rainwater can be.

There are installation sites where backflow occurs during heavy rain the sewage system can occur. With normal Property drainage it is common Backflow stops to be provided if the Drainage point not laid over the backflow level can be. The receptacles on transshipment points can filled up with a backwater; then they would be for you later incident no longer available. According to the invention this malfunction is countered by the fact that in the Pipeline responsive to backwater Backflow sensor is provided on the shut-off device in Closing direction is switched. Preferably, the Backflow sensor seen in the backflow direction before Shut-off device, and at such a height that it opens normal rainwater drainage does not respond. In Embodiment of the invention, the backflow sensor can then also in the normal drainage direction in front of the shut-off device lie, in the area of the overflow opening, the preferably the upper limit of those provided there housing-like extension of the pipeline. The feeler can be installed and removed through the overflow opening being repaired.

To simplify the construction of the system, it is advisable the backflow sensor with the liquid sensor for the dangerous liquid to a combined sensor unite. The circuit of the combined sensor on the  Shut-off device is then such that it is normal Rainwater drain does not respond, but does respond to backwater, with closing the shut-off device, and that the shut-off device in the presence of liquid in the area of the sensor remains closed. By blocking the backwater remains the container for the dangerous liquid available. The accumulated in front of the shut-off device Liquid must be examined by the safety officer and be removed if dangerous. Even if it is safe backwater is involved, it must be removed before the shut-off device is released again.

If the backwater caused by heavy rain is also Drainage at the transshipment point itself affected. The rain would by closing the shut-off device in the Collection container directed. The container would have to afterwards be pumped empty. To avoid this disadvantage, in a further embodiment of the invention, a second, Shut-off device arranged in front of the overflow opening provided by a just below the Overflow opening driven liquid sensor becomes. This shut-off device can only be opened again when the backflow sensor stops the backflow has signaled. Because then it can be assumed that also the heavy rain has ended. That before the second Shut-off rainwater can enter the sewage system flow as soon as it is examined as harmless and the first Shut-off device has then been opened.

It is useful to add another container  Equip liquid sensor, the presence of Liquid reports.

The illustrations show several exemplary embodiments for Drainage facilities on a transshipment point for water polluting liquids.

The floor drain 2 shown in Fig. 1 is part of a liquid-tight bottom plate 1, which also receives the first portion of the drain tube 3. A sufficiently large sludge trap made of reinforced concrete serves as the collecting container 4 . Inlet and outlet connections 5 , 6 are connected by a continuous pipe section 7 , into which a housing-like extension 8 with an upper overflow opening 9 is integrated. In the flow direction behind the extension, the pipe section 7 is interrupted by a shut-off element in the form of a motor-driven slide 10 . A liquid sensor 11 is attached to the wall of the extension at a height at which it is not wetted by normal rainwater runoff. Another liquid sensor 12 is installed on the bottom of the collecting container 4 . It scans for liquid in the container. Both sensors are connected to a controller 13 , in which the pulses of the sensors are processed logically and converted into closing and opening commands of the slide 10 and on which the alarm can also be indicated optically or acoustically.

When the transshipment point is empty and the collecting container is empty, the slide 10 is open. Rainwater can flow freely into the sewage system, and full pipe filling does not trigger the sensor 11 either.

As soon as a tanker truck drives through the transhipment point, the slide is closed automatically, e.g. B. by connecting the filler neck or hose. If liquid is inadvertently escaped, it is passed through the overflow opening into the collecting container and stored there. The sensor 11 installed under the overflow opening responds and triggers an acoustic alarm which causes the refilling process to be stopped immediately. The collected liquid must be sucked out of the container and on the pipe section before proceeding with the handling or before the slide can be opened again after the handling has been completed.

If a backflow from the sewage system occurs when the transshipment point is empty, the sensor 11 is wetted before the backflow water reaches the collecting container 4 via the overflow 9 , and the slide is closed immediately. "Backflow" is displayed on the display board 13 . After the backflow has subsided, since the sensor is still wetted by the liquid in tube 7 , the backwater must first be removed. Then the slide can also be opened again.

If it is handled during a backwater and dangerous liquid enters the drain, it is held back by the closed slide valve and directed into the collecting tank, displacing the backwater in the pipe section 7 . If the backflow subsides during this fault, the slide remains closed, as the sensor still reports "liquid". Even if there is no fault during the backflow, the slide remains closed. By connecting the filling line, the closing command is given priority over the closing command by backwater, so that the slide cannot be opened even if the backwater has been pumped out of the pipeline.

In the system according to FIG. 2, a revision shaft 15 is switched into the line 14 leading to the collecting duct, in which waste water samples can be scooped. At the outlet of the inspection shaft 15 , the sensor 11 'is attached, which projects with its sensor probes in the upper part of the clear cross section of the outlet opening. At the inlet a manually operated quick release slide 16 can also be provided, the z. B. can be closed in the event of a power failure and then keeps the system functional. The valve can also be closed in the event of a backwater, but must then be opened again after the backwater has subsided, so that no rainwater flows into the collecting container during normal rain events.

In the third embodiment of FIG. 3, an automatic backflow valve 17 is installed in the revision shaft 15 ', which is actuated with compressed air generated by a compressor. He also has a manually operated slide 16 'for safety, which can be closed in the event of a power failure. Between the two closures lies in a pipe extension of the sensor 11 '', which provides the impulse to close the two closures.

Claims (9)

1. Plants for filling and handling water-polluting liquids, with a floor drain ( 2 ) connected to the sewer through a pipe ( 3 , 7 , 14 ) for the removal of rainwater, and with a collecting container ( 4 ) traversed by the pipe ( 7 ) for the water-polluting liquid that escapes in the event of a fault, the pipeline ( 7 ) having a shut-off device ( 10 , 16 ') closed in the presence of a tanker and an overflow opening ( 9 ) in front of it in the collecting container ( 4 ), characterized by a backflow sensor ( 11 , 11 ', 11 ''), which is connected to the shut-off device ( 10 , 16 ' in the closing direction). 2. Installation according to claim 1, characterized in that the backflow sensor ( 11 ) is arranged in the region of the overflow opening ( 9 ) at such a height that it is not wetted by normal rainwater drainage. 3. Plants according to claim 2, characterized in that the pipe ( 7 ) in the area of the overflow opening ( 9 ) and the backflow sensor ( 11 ) expanded like a housing and z. B. is designed as a sampling shaft. 4. Plant according to claim 1 to 3, characterized in that for the presence of water-polluting liquid in front of the closed shut-off device ( 10 ) there is a second sensor which is connected to the shut-off device ( 10 ) so that this only in the absence of liquid can be opened. 5. Plant according to claim 1 to 3, characterized in that the backflow sensor combined with the sensor in front of the shut-off device ( 10 ) to form a combined sensor ( 11 ) and this combined sensor ( 11 ) is connected to the shut-off device so that the shut-off device ( 10 ) is closed when backwater occurs and remains closed in the presence of liquid. 6. Plant according to claim 5, characterized in that the sensor ( 11 , 11 ', 11 '') triggers a display "back pressure" when the sensor ( 11 , 11 ', 11 '') with an open shut-off device ( 10th ) senses the presence of liquid, and that a "malfunction" indicator is triggered when the sensor ( 11 , 11 ', 11 '') senses the presence of liquid when the shut-off element ( 10 ) is closed. 7. Plant according to claim 1 to 6, characterized by a second, in front of the overflow opening ( 9 ) arranged shut-off device which is controlled by a liquid sensor located just below the overflow opening such that it is closed by the presence of liquid and only in the absence of Backwater behind the first shut-off device ( 10 ) can be opened. 8. Plant according to claim 1 or 4, characterized in that the collecting basin ( 4 ) is followed by a separate inspection shaft ( 15 , 15 ') in which the backflow sensor ( 11 ', 11 '') is housed. 9. Plant according to claim 8, characterized in that at the inlet into the inspection shaft ( 15 ') an automatically operated by the backflow sensor ( 11 '') backflow valve ( 17 ) is arranged.