DE19930346A1 - Sewer rinser; has flood chamber connected to collecting chamber and having blocking organ to close ventilation opening, connected to floats in collecting and flood chambers - Google Patents

Abstract

The sewer rinser has a flood chamber (3) connected to a collecting chamber (1). A closure body (2) for a collecting chamber rinsing opening and a downwards-facing flood chamber inlet (4) opens when the flood chamber is flooded. The flood chamber has a ventilation opening (7) with a blocking organ (8), which is connected to floats (10,11) arranged inside the collection chamber and the flood chamber, or to pressure sensors.

Description

The present invention relates to a channel washer with a collecting space for Flushing liquid, which has a flushing opening towards the channel to be flushed, one Flood space, which is connected to the collecting space via a flood space opening, and a closure body, the flush opening and the Closes the flood space opening and the two openings when the flood space floods releases.

Such sewer flushers are usually used for sanitary or sewerage automatically, preferably using collected surface water, to wash. The sewer networks in settlement areas are increasing on Separation drainage aligned. Over the sewage sewer network only the heavily polluted waste water is sent to the sewage treatment plant. The rainwater should seep away as possible or be fed directly to the natural river.

As a result of the separation drainage, the water remains in the waste water channels Rainwater sporadically induced natural flushing. In many In some cases, this inevitably leads to deposits that cause unpleasant odors and lead to constipation. To remove the deposits, the  Channels, especially on the end strands, on a slight slope and / or with ge ringer water supply are flushed at regular intervals.

In practice, the sewer network is flushed mainly with mobile cleaning devices and is therefore expensive and unsanitary. Often for the sink practiced direct connection of a gutter drain or a street The drainage on the sewer does not bring the desired success because not a strong one from the rainwater inflow arising from the precipitation Dishwashing power arises. Such small flushing drains, which are particularly common in the small rain with low intensity appear, spread quickly and work - if at all - only over a short distance.

In order to achieve greater washing power, the washing liquid can first be in one Collecting space can be collected until a larger amount of rinsing liquid is collected, which then gushes with great washing power into the channel to be washed is drained. From DE-PS-21 81 85 is a channel washer of the beginning ten kind known. An overflow pipe is provided here as a flood space. With floods of the Overflow pipe creates an upward water pressure on the closure body per, whereby the closure body, which was previously mainly wetted only from above floats and releases the flush opening.

The temporary flooding of the flood space is just like the filling of the collecting space depends on the volume flow of the amount of water flowing into the sewer.

Even in heavy rain events, the volume flow of a gutter or Road drainage relatively sparse; from the much more common little low Quite apart from beat events.  

The following problem arises for the operation of the above-mentioned sewer cleaner:
The flood space fills up relatively slowly with a small inflow quantity. The counter pressure on the closure body grows with the liquid rising in the flood space. Here, a limit water level is reached during the increase in liquid in the flood zone, which means that at this water level level just so much counter pressure is exerted on the closure body that it begins to lift from its fluid-tight seat. When the limit water level is reached, the water in the flood area is already escaping through the flushing opening, which is no longer completely sealed. As a result, the water level in the flood zone drops, the counterpressure on the closure body diminishing, so that the closure body is brought back into the closed position by the greater water pressure present in the collection chamber.

Repeats itself according to the volume flow flowing into the sewer this process any number of times without the actual rinsing process is resolved. With known devices, such as one of the liquid Mirror of the collecting space controlled overflow closure or a lifter this problem cannot be solved because the function of such devices is analogous to egg N overflow pipe subject to the direct liquid supply and therefore no shock enable like or forced filling of the flood space.

It is therefore the object of the present invention to provide a channel washer gangs mentioned type in such a way that the rinsing process in a simple manner is also triggered automatically when the volume flow of the inflow flows liquid is relatively low. This object is achieved according to the in claim 1 marked features.  

The design of the flood space is essential to the invention. This exists of an inlet opening facing downwards for the flood zone and a vent tion opening, which is provided with a shut-off device, which on the one hand over the Water level of a float or pressure in the collecting room and on the other hand via the water level of one located in the flood area Float or pressure transducer is actuated.

If the initially empty collecting space is filled with incoming rinsing liquid, then the closure body is in the closed position and simultaneously locks the Flood opening of the flood space and the flushing opening towards the channel from air and fluid tight. The rinsing liquid rises in the collecting space, the one pointing downwards Inlet opening of the flood space immersed in the rinsing liquid of the collecting space and thus closes the interior of the flood space from the atmosphere.

At the same time, one is preferred during the filling of the collecting space Vents arranged above the highest water level in the collecting room opening of a shut-off device via its own weight and / or via a spring force acting on the shut-off device is sealed airtight. The vent However, below the max. Liquid level of the collecting room be arranged.

In this phase, the air trapped in the flood area cannot escape, so that no liquid can enter the flood space from the collecting space. Has the in Collecting space ascending rinsing liquid the selected storage target for rinsing aisle reached, then a collecting room float arranged in the collecting room becomes or pressure transducer, which is connected to the shut-off element in a non-positive manner is moved up. The float in the common room lifts this through its buoyancy Shut-off device from its seat, the one under pressure in the flood area closed air flows out through the ventilation opening and thus rinsing liquid  through the inlet opening of the flood space from the collecting space into the flood space penetrates.

As a result, the water level in the water drops when the feed liquid is relatively low Collection room again. This causes the float to move again down and the associated shut-off device ver closes the vent.

In relation to the incoming rinsing liquid, this process is repeated so often until the increasingly dammed up liquid in the flood space Flood space arranged flood space float or pressure transducer actuated. Here is essential to the invention that the flood chamber float or pressure transducer under half of the boundary water level begins to work.

The flood float is also motion-locked with the shut-off device connected and designed such that this with increasing liquid level in the Flood space regardless of the function of the pool float blocking element preferably moves upwards and so the vent opening completely dig releases. The air now escaping leads to an intensified and unstoppable Men fluid entry into the flood space, and now and the shut-off device itself can no longer close when the water level in the collecting room falls. Thus fills the flood space is forced due to the water pressure difference to the collecting space and suddenly with rinsing liquid. The flood space and the flood space opening are of this type dimensioned that in this phase more water from the collection room in the Flood space can flow in as at the moment of floating of the breech block pers can expire when the flush opening is released. The flow cross section of the Inlet opening and that of the flood space are therefore preferably larger than that Flow cross section of the flushing opening is formed.

Analogous to the collecting room, the flood space is now approximately the same size Water pressure, whereby the closure body floats up and so the rinse process is triggered.  

A particular advantage of the subject matter of the invention is the simple technology at re relatively large and thus deposit and blockage-free flow cross-sections. The invention is explained in more detail using an exemplary embodiment.

It shows the

Fig. 1 is a longitudinal section of the scavenging port and sealed at Kanalspülers filled collection chamber during the filling phase of the flood chamber,

FIG. 2 is a detailed section of the flood space forming the invention at the beginning of collecting space filling,

Fig. 3, Fig. 2 with a filled collection chamber into the phase of the successive flooding-chamber filling,

Fig. 4, Fig. 2 in the phase of the forced flood space filling.

Fig. 1 shows an embodiment with an integrated in a manhole 12 th channel washer. The canal washer consists of a collecting space 1 for the storage of the rinsing liquid, a flood space 3 which is connected to the collecting space 1 via a flood space opening 4 , a closure body 2 which, in the closed position shown, closes the flushing opening 5 to the channel 13 and closes the flood space opening 4 .

The flood space 3 has a downward inlet opening 6 which is immersed in the rinsing liquid, the flood space region above the inlet opening 6 being arranged, for example, in a bell shape with an annular inlet opening 6 around the lower flood space region. Due to the air trapped there, the flushing liquid cannot penetrate into the flood space 3 . The preferably above the max. Liquid level 14 in the collecting space 1 arranged vent 7 is closed by a shut-off 8 . At this shut-off element 8 , a floating body designated as a collecting space float 10 is arranged within half of the collecting space 1 and is connected to the shut-off element 8 in a non-positive manner. In addition, a floating body designated as a flood space float 11 is arranged within the flood space 3 , which is also connected to the shut-off element 8 in a movement-locking manner and thereby preferably penetrates the ventilation opening 7 with its connecting element 9 .

The lower end of the flood float 10 is arranged below the Grenzwasserspie gels 15 .

Fig. 2 shows the hydraulic conditions in the phase at the beginning of the collecting room filling. The flood space 3 is completely empty. The vent opening 7 is closed airtight by the shut-off element 8 . The inlet opening 6 is closed by the rising liquid level in the collecting space 1 against the atmosphere ver. The air trapped in the flood space 3 cannot escape.

Referring to FIG. 3 of the collecting chamber 1 is filled. The collecting chamber float 10 lifts the flood chamber float 11 , which is initially still inoperative, and the shut-off element 8 in its seat, the ventilation opening 7 being partially released and the air in the flood chamber 3 escaping under pressure. At the same time, liquid flows into the flood space 3 via the inlet opening 6 . Until the limit water serspiegel 15 is reached, the inflowing liquid in relation to the outflowing amount of air is collected in the flood space 3 .

Reaches the liquid level that builds up in the flood zone 3 as shown in FIG. 4 the flood zone float 10 arranged below the limit water level 15 , then the shut-off element 8 is raised via its buoyancy forces and thus the vent 7 is increasingly released. This leads to a zwangswei sen and abrupt filling of the flood space 3 , so that there is approximately the same surface of water as in the collecting space 1 . The upward water pressure now acting on the closure body 2 lets it float and releases the flushing opening 5 for the flushing process.

The floats 10 , 11 or pressure transducers are the preferred embodiment with the shut-off element 8 ; but they can also be coupled to one another via a lever mechanism.

Likewise, the shut-off element 8 and the ventilation opening 7 can be arranged in relation to one another in such a way that the ventilation opening 7 can also be closed and released from below or from the side and can also be arranged below the liquid level in the collecting space.

Instead of the float 10 , 11 , pressure transducers (membrane) can be inserted, via which the shut-off element 8 can be actuated.

The formation of the flood space 3 can have any shape. For operational reasons, however, it is advantageous if the flow cross section of the inlet opening 6 and the area of the flood space 3 through which the flushing opening 5 flows are larger than the flow cross section of the flushing opening 5 .

Claims (5)

1. channel washer with a collecting space for flushing liquid, which has a flushing opening to the channel to be flushed out, a flood space which is connected via a flood space opening to the collecting space, and a closure body which closes the flushing opening and the flood space opening in its closed position and in the event of flooding of the flood chamber clears the two openings, characterized in that the inlet opening ( 4 ) of the flood chamber ( 3 ) is directed downwards and that the flood chamber ( 3 ) has a ventilation opening ( 7 ) with a shut-off device ( 8 ) which is connected to an inside of the collecting space ( 1 ) and with an inner half of the flood space ( 3 ) arranged float ( 10 , 11 ) or pressure transducer is connected in a movement-locking manner. 2. Channel washer according to claim 1, characterized in that the lower end of the flood chamber float ( 11 ) or the pressure transducer is arranged below the boundary water level ( 15 ) of the flood chamber ( 3 ). 3. Channel washer according to claim 1, characterized in that the shut-off element ( 8 ) is conical. 4. sewer washer according to claim 1, characterized in that the flow cross section of the inlet opening ( 6 ) is greater than the flow cross section of the rinsing opening ( 5 ). 5. sewer washer according to claim 1, characterized in that the flow cross section of the flood space ( 3 ) is greater than the flow cross section of the flushing opening ( 5 ).