NL9100473A - Sewage outflow system with overflow protection - provides automatic selection of solid waste for treatment and water to overflow under extreme conditions - Google Patents

Abstract

In a sewage system with natural fall the main header (2) directs normal flows into the treatment works (3). A branch from the header runs into an overflow basin. When due to extreme conditions flow exceeds the capacity of the treatment works the sewage is separated (7) upstream of the branch into water and sludge. Under these conditions the sludge remains in the main header to flow to the treatment works and the water is directed to the overflow basin. As a result toxic materials are prevented from entering the overflow environment and thus present a health hazard. The system automatically returns to total flow into the works when conditions return to normal.

Description

Sewer system

The invention relates to a sewer system with a free fall, comprising a main pipe leading to a waste water purification device or the like and a branch pipe connecting thereto, which runs to a discharge location.

Such a sewer system can be used for the collection and transport of waste water and / or precipitation. In dry weather, all collected wastewater can be transported to the wastewater treatment plant. The supply of the precipitation contribution in particular, however, exhibits such extreme variations in time that it is financially and technically impossible to realize a sewer system with which the entire supply of precipitation and waste water can be transported under all conceivable circumstances. For this reason, it is accepted in practice that a sewer system discharges to surface water at the discharge site with limited regularity, for example via overflow thresholds. However, the composition of this discharged water is such that there is a risk of damage to the surface water environment, such as short-term oxygen depletion, and long-term accumulation of persistent substances such as heavy metals in biomass and underwater bottom.

Research has shown that solids (sewage sludge) generated during the discharge of sewage into the sewage pipes contains a considerable part of the substances responsible for this damage. To date, efforts have been made to limit the discharge of harmful substances from sewer systems by taking special measures, such as increasing the storage capacity of the sewer system, expanding the pumping capacity, using storage settling basins or swirl overflow pits and expanding the maintenance of sewer systems. However, these measures have not proved sufficiently effective and / or too expensive.

The object of the invention is to improve a sewer system of the type mentioned in the opening paragraph in such a way that the said problem is effectively solved or reduced.

To this end, the sewer system according to the invention is characterized by distributing means for distributing a flow through the main pipe in the main pipe, in the part before the branch pipe, in a relatively silt-rich and low-sludge part; and separating means for separating the low-sludge and sludge-rich part from each other and passing the sludge-rich part through the main pipe and guiding the low-sludge part to the branch pipe.

Since, according to the invention, a distribution and separation of low-sludge and high-sludge water already takes place in the main pipe, on the one hand relatively clean water is discharged, while on the other hand a large part of the sludge with the impurities present therein is transported directly or indirectly to the wastewater purification installation.

In a very simple embodiment of the sewer system according to the invention, the distributing means are provided with means for gravity lowering sludge into the stream, while the separating means are arranged for separating the stream in the main line in a vertical direction.

By using gravity to separate the largely heavy sludge, in principle simple means will suffice and existing sewer systems will be easy to adapt.

A favorable example of this embodiment is that in which the distributing means consist of a tube with at least approximately a smooth inner wall, while the separating means are provided with a dividing wall running at a certain height, running transversely through the main pipe, with a space above the dividing wall with the branch pipe. connection.

In this sewer system, use can be made of parts which are already present in existing sewer systems and the invention is therefore cost effective in that respect. Furthermore, the operation is independent of mechanical, pneumatic or electrical parts and, consequently, the robustness and reliability required in sewage practice is guaranteed.

A further optimization of the distribution and separation of the sludge-rich and low-sludge stream can be achieved if a number of distribution and separation means are placed alternately one behind the other.

In this way a division and separation takes place a number of times.

It is hereby possible to construct the sewer system with at least two stages with a first and second branch pipe from the main pipe, the second branch pipe having an adjustable restriction for limiting the maximum flow rate in the part of the main pipe between the first and second branch pipes.

This measure guarantees good sedimentation conditions in the main line under all circumstances. The adjustable restriction can be very simple and in most cases only needs to be adjusted once, after which it can be secured. A possible embodiment may consist of a slide arranged in the pipe.

Preferably, the main pipe is fitted with a relatively strong run-out, in order to ensure that during dry weather situations a relatively large suspension of the water in the pipe is created, which results in a relatively large soil shear stress and thereby a build-up and entrainment of accumulated sludge in the main line.

The invention will be elucidated hereinafter with reference to the drawing, which schematically shows an embodiment of the sewer system according to the invention.

Fig. 1 is a schematic of an exemplary embodiment of the sewage system according to the invention.

Fig. 2 is a very schematic side view, partly in section, of a part of the sewer system according to FIG. 1.

Fig. 3a-3d show the sludge concentration distribution over the height of the main pipe of the sewer system of fig. 2, at four different locations lilac-illd therein.

The principle diagram according to Fig. 1 shows that a sewer system of wells, connections and pipelines, indicated with a block 1, opens into a main pipe 2 leading to a waste water purification installation 3, where the waste water can be cleaned of contaminants. The sewer system shown is a so-called mixed sewer system, in which waste water from, for example, households or companies, as well as precipitation is collected. For situations in which more waste water and precipitation is supplied than can be processed in the waste water purification installation 3, a first branch line 4 connects to the main line 2 which leads to a discharge location 5, where excess sewage water can be discharged into surface water, for example via an overflow threshold. Seen in the direction of flow in the main line 2, a second branch line or short-circuit line 6, which opens into the first branch line 4, connects to this main line 2 at a distance after the first branch line or overflow line 4. The main line 2 is thereby divided into a first section 2 'before the first branch line 4, a second section 2' 'between the two branch lines 4 and 6 and a third section 2 * after the second branch line 6. For clarity, in fig. 2 the branch lines 4 and 6 are drawn above the main line 2, but in reality they will usually run in the side direction at the same height as the main line 2.

Fig. 2 shows the particular connections of the branch lines 4 and 6 to the main line 2, as proposed by the invention. At the junction of the pipes 4 and 2, a horizontal partition wall 7 is arranged at a certain height in the main pipe 2, the space above this partition wall 7 being in communication with the branch pipe 4, while the space below the partition wall 7 forms part of the main pipe 2. A comparable dividing wall 8 is also provided at the junction of the pipes 6 and 2, the space above the dividing wall 8 connecting to the second branch pipe 6 and the space below the dividing wall 8 being part of the main pipe 2 The cross-section of the main pipe 2 under the partitions 7 and 8 must be large enough to allow sufficient waste water to pass through for processing in the waste-treatment plant 3.

The operation of the part of the sewage system according to the invention shown in the drawing is as follows.

Wastewater and precipitation are supplied through section 2 of the main pipe 2. The waste water contains solid components which have a greater specific gravity than water and can therefore settle therein. These settable components will settle and therefore end up in the lower part of the flow through the main line 2. Such settling of heavier solid components of the waste water can be favorably influenced by excluding turbulence-causing elements from the main pipe 2 and thus designing it as a tube with the smoothest possible inner wall and sufficient length. With a sufficient length of the section 2 'of the main line 2, the concentration distribution of solids or sludge in the vertical direction of the main line 2 will change from the situation according to Fig. 3a at the beginning of the line part 2' to the situation as shown in Fig. 3b. In both cases the height of the main pipe 2 is plotted on the vertical axis, while the horizontal axis is plotted the concentration of solids or sewage sludge. It can be seen that in the situation according to Fig. 3b the upper part of the flow through the main line 2 is relatively low in sludge, while the lower part of the flow through the main line 2 is relatively high in sludge. When this flow arrives at the dividing wall 7, the relatively silt-rich part will flow under the dividing wall 7 and end up in the part 2 '' of the main pipe 2, while the relatively low-sludge part of the flow is separated by the dividing wall 7 from the other part and fed to branch line 4.

In the section 2 '' of the main line 2, the same sagging process will occur for that part of the stream that flows further below the dividing wall 7 into the main line 2 as in the section 2 '(cf. fig. 3c and 3d). In the section 211, this process can be enhanced by limiting the flow rate of the wastewater, which already occurs because the flow rate through the section 2 '' of the main pipe 2 is smaller than through the section 2 ', so that the flow rate in the section 2 1 will be lower when the diameter of the main line 2 remains the same. At the end of the section 2'1 of the main line 2, the sludge concentration distribution according to Fig. 3d has arisen and the partition 8 again separates the sludge-poor and sludge-rich water, whereby the low-sludge water is fed to the discharge site 5 via the branch pipes 6 and 4, while the sludge-rich water is transported through the main pipe section 21'1 to the waste purification device 3. At the discharge location 5, the water arriving there therefore still contains only that part of the solids originally present in the waste water flow, which floats in the upper flow at the partition walls 7 and 8.

The flow velocity in the main pipe section 2 '' must remain below a certain critical value during overflow situations, in order to ensure a sufficient sedimentation of sludge. This can be achieved by placing a restriction in the second branch line or short-circuit line 6, such as, for example, by an adjustable slide 9 in the second branch line 6. The resistance in this second branch line 6 must therefore be such that the flow velocity in the main pipe section 2 '' cannot exceed a maximum value. In this way, an optimum separation efficiency between sludge-rich and low-sludge wastewater is achieved and it is ensured that relatively little sludge with any impurities therein is discharged into the surface water. According to calculations, with the sewage system according to the invention, 80% of the settable fraction can be separated for supply to the waste water purification plant.

In a dry weather situation, the capacity of the main pipe 2 and the waste water purification device 3 will be large enough to process all the waste water, so that all the waste water with sludge therein will flow under the partitions 7 and 8 and through the main pipe 2 to the waste water purification plant 3 will be fed. By ensuring that a relatively steep waterline in the main pipe 2 and in particular in the part 2 '' thereof is created in drier situations, and therefore a relatively large soil shear stress in the pipe, it will occur in the pipe 2 during precipitation situations. Accumulate accumulated sludge and are carried along to the wastewater treatment plant 3. This can be achieved by lowering the main pipe 2 and in particular its part 2 '' relatively strongly, for example on the order of 2 m per km of pipe length . The length of the part 2 * 'of the main pipe 2 will normally be several hundred meters. Incidentally, the branch pipes 4 and 6 should preferably be laid out such that they can drain in the direction of the pipe section 2 '' 'of the main pipe 2 under the influence of gravity after a rain shower has ended.

From the foregoing, it will be apparent that the invention provides a sewage system in which the discharge of sewage sludge to surface water is considerably limited, while this is achieved without mechanical, pneumatic or electrical parts, while still controlling the flow conditions under which the separation process is taking place. The invention can be easily integrated into an existing sewage system using existing components and therefore causes lower costs compared to current practice. Furthermore, incorporation of the invention into a sewer system takes up little space.

The invention is not limited to the exemplary embodiment shown in the drawing and described above, which can be varied in various ways within the scope of the invention. For example, the main pipe of the sewer system could also lead to a place other than a wastewater treatment plant, for example to a flow field or another type of discharge site, where more contaminated water may be discharged than at the discharge site 5. Furthermore, the invention can also be applied in a sewage system for rainwater only or waste water only, instead of the mixed sewage system described above.

Claims (7)

Sewer system with free fall, provided with a main pipe (2) running to a waste purification device (3) or the like and a branch pipe connecting thereto, leading to a discharge location (5), characterized by distributing means for feeding into the main pipe ( 2), in the section (2 ') in front of the branch line, dividing a flow through the main line into a relatively silt-rich and low-sludge section; and separating means (7) for separating the low-sludge and sludge-rich part from each other and passing the sludge-richer part through the main pipe (2) and guiding the low-sludge part to the branch pipe (4). Sewer system according to claim 1, wherein the distribution means are provided with means (2) for gravity lowering sludge into the stream, while the separating means (7) are arranged for separating the stream in the vertical direction. main pipe (2). Sewer system according to claim 2, wherein the distribution means consist of a tube (2) with at least approximately smooth inner wall, while the separation means are provided with a partition wall (7) running transversely through the main pipe, wherein a space above the partition wall is in communication with the branch pipe. Sewer system according to claim 1, 2 or 3, wherein a number of dividing (2 ', 2 * 1) and separating means (7, 8) are placed alternately one behind the other. Sewer system according to claim 4, having at least two stages with a first and second branch pipe (4, 6) from the main pipe (2), the second branch pipe (6) having an adjustable restriction (9) for limiting the maximum flow rate in the section (211) of the main line (2) between the first and second branch lines (4, 6). Sewer system according to claim 5, wherein the adjustable restriction (9) consists of a lockable slide or the like. Sewer system according to any one of the preceding claims, wherein the main pipe (2) drops at least partly relatively strongly.