WO1998015502A1

WO1998015502A1 - Method for sewage treatment in small treatment plants

Info

Publication number: WO1998015502A1
Application number: PCT/EP1997/005559
Authority: WO
Inventors: Peter Bracher
Original assignee: Peter Bracher
Priority date: 1996-10-10
Filing date: 1997-10-09
Publication date: 1998-04-16
Also published as: CN1233232A; DE19641681A1; HUP0000234A3; HUP0000234A2

Abstract

A method for sewage treatment in small sewage treatment plants with at least two chambers (1, 2). Sewage (A) passes into the first chamber (1) where heavier solid matter (F) settles at the bottom and a fluid fraction (L) of the sewage is directed towards the other chamber (2) where bacteria beds are placed in order to set up bacterial colonies and aerobic decomposition of the still existing constituents occurs and a drained, clarified water body (w) arises. According to the invention, part of the drained and clarified water (w) flows, by suction of flowing fraction (L) of sewage carried out by a first pump device (4) in a following chamber (2), back into the top section of the first chamber (1) through one or more openings (Ö). Further, biomass layer which continuously stems from bacteria beds is redirected to bacteria beds (3) by suction of the water layer existing below the bacteria beds (3) via a secon d pump device (7) from their top section and outside the stationary liquid. Pump devices (4, 7) are programmed to operate with interruptions.

Description

Process for wastewater treatment in small wastewater treatment plants

The invention relates to a method for wastewater treatment in small sewage treatment plants, in particular using existing small sewage treatment plants with two or more chambers.

Wastewater treatment processes in small wastewater treatment plants are known and are still widely used, particularly in rural areas with small settlements that cannot be connected to a large central wastewater treatment plant due to the small quantities involved and the long distances involved. The wastewater is usually fed to a multi-chamber pit. Undissolved solid substances are mechanically separated in the first chamber. Heavier solid substances settle on the floor, while floatable substances on the surface e.g. B. held back by baffles.

Mer in the first, the so-called Einlaufka, and in the other chambers, usually there are so-called Three ^¬ chamber dug, then the remote or dissolved organic African substances partially broken down anaerobically. The wastewater pre-cleaned in this way is finally z. B. initiated in existing waters or in public drainage systems or z. B. fed to the ground via seepage shafts. The mechanically separated solids are removed from the first chamber at regular intervals, shut down and z. B. further processed in a large biological treatment plant. These systems, which are still widely in use, have the disadvantage that insufficiently clarified wastewater can enter water bodies and pollute them due to insufficient biodegradation of the ingredients. Furthermore, due to the anaerobic degradation processes, these pits often lead to unpleasant odor nuisance, and the regular removal and further treatment of the deposited thick matter is complex and expensive.

There have therefore been attempts to improve the situation described. DE-3 837 852 C2 describes a small sewage treatment plant with a multi-chamber pit, in which one or more intermediate chambers are provided by converting existing pits, in which a largely aerobic degradation of the organic pollutants of the waste water can take place through the arrangement of ventilation devices and fixed beds , Air is drawn in via a blower and pressed into the waste water close to the bottom of the intermediate chamber. The fixed beds are located above the air inlet openings and serve the increased colonization with microorganisms. An additional agitator can be provided in the intermediate chamber to further enhance biodegradation.

The small sewage treatment plants modified in the manner described improve the known degradation processes in that they ensure a higher degree of degradation as a result of the largely aerobic degradation of the organic constituents of the waste water in the intermediate chamber (s) and the pollution of the water and the soil into which who operate in this way purified wastewater are discharged. The disadvantage of these clarification processes is that the solid constituents contained in the wastewater, which collect in the inlet chamber, are still only subjected to an anaerobic degradation process, and that the odor nuisance emanating from this chamber persists. Also, the accumulating thick matter in the same way as before regularly run and z. ^' B. further processed in a large sewage treatment plant. The main disadvantage of this method, however, is the need to convert the existing pits by erecting partitions and a relatively high outlay on equipment, which at the same time requires a high expenditure of energy.

It is therefore an object of the invention to develop a process for wastewater treatment in small sewage treatment plants which enables effective aerobic degradation of the organic pollutants, in which existing small sewage treatment plants can be used without or with only minor conversion measures, and in which the outlay in terms of equipment and energy expenditure is significantly reduced compared to known methods.

The invention is solved by the characterizing features of claim 1. Advantageous embodiments of the invention are characterized in the subclaims 2 to 7.

The invention will be explained in more detail below using an exemplary embodiment in conjunction with the drawings according to FIGS. 1 to 3.

Figure 1 shows schematically the process flow using a septic tank with two chambers.

FIG. 2 shows the appropriate arrangement of the equipment necessary for the process in a three-chamber septic tank. FIG. 3 shows the flow diagram of the process sequence according to the invention.

As mentioned, FIG. 1 first shows the process sequence according to the invention using a septic tank with two chambers. Waste water A occurring in a building G is fed through an inlet Z to a first chamber 1 of a small sewage treatment plant. The heavier solids F settle in the first chamber 1 in a known manner. When the level of the openings ö is reached, the liquid part of the waste water flows into the second chamber 2 of the small wastewater treatment plant. In this second chamber 2, growth bodies 3 are arranged which are populated with bacteria which, when supplied with oxygen, first break down the organic dirt load (CSV) and, in the case of advanced CSV degradation, also break down the ammonium present (nitration). The nitrate ion depends on the decrease in the CSV concentration, on the oxygen concentration and on the temperature. The oxygen required for aerobic degradation is entered by taking care, on the one hand, of an unimpeded flow of air via the septic tank from the ventilation opening E of the building G to the outlet opening 6 of the septic tank, i.e. air rises from the outlet of the system 6 to the roof of the Building G to the top. The actual entry of the atmospheric oxygen takes place by means of the two first and second pump devices 4 and 7. The input of the first pump device 4 is located in the first chamber 1 at a location below an upper layer area 5 of the unpurified liquid part L of the waste water A. The first pump device 4 conveys this to a location above the growth body 3 in the second chamber 2, and allows it to flow freely into the growth body 3 through the air. The second pumping device 7 is arranged near the base of the second chamber 2 and conveys cleaned biorases with the fallen off growth bodies to a location above the growth bodies 3 in the second chamber 2, so that the free fall of the Gang of the circulating pump 7 flowing liquid oxygen is entered. At the same time, as a result of the suction of waste water by means of the pump device 4, purified, oxygen-enriched water W which has been drawn out of the chamber 1 from a location below an upper layer region 5 flows out of the chamber 2 through the water through the opening δ in between the chambers 1 and 2 existing partition back into chamber 1.

If existing two- and multi-chamber pits continue to be used, these openings must be retrofitted. The outlets of the opening der on the side of the chamber 1 are advantageously directed upward in order to avoid a cross flow in the chamber 1. As a result, the solids F deposited at the bottom of the chamber 1 and a lower region of the liquid part of the waste water A are overlaid with depleted, purified, oxygen-containing water W. This primarily means that odor nuisance from the overlaid layers is avoided. On the other hand, however, oxygen enrichment also takes place in this lower region, so that here, too. T. aerobic degradation of the dirt load occurs because the organic load is diluted with wasted and cleaned wastewater.

In Figure 2, the conversion of a three-chamber pit is shown in plan view and in a side sectional view AA. Such three-chamber pits in particular are still widely used in rural areas. In such three-chamber pits, the chamber 1 still serves as a settling tank for settling the heavier solids in the process according to the invention. The partition T between the other two chambers can be broken off, so that a large chamber 2 is formed. If the partition T is not broken off, the previous two chambers act as a common chamber 2. The chamber 2 formed in one way or another is equipped with growth bodies in the manner described above. The wastewater flow is conducted in the same way as this has already been described with reference to FIG. 1.

The wastewater to be cleaned is introduced into chamber 1 via inlet Z. The pump device 4 sucks the liquid part L of the waste water A from a point below an upper layer area 5 (see FIG. 1 in this regard) and conveys it to a point above the growth bodies 3 in the second chamber 2 and leaves it free-falling through the air flow into the growth body 3. With the free-flowing inflow, oxygen accumulation of the waste water takes place, so that an aerobic breakdown of the organic dirt load (CSV) and also an ammonium breakdown (nitrate ion) can take place in the growth bodies 3. The biorase falling in chamber 2 is sucked in by the second pumping device 7, which is arranged in the chamber 2 near the bottom, and is also brought back into the chamber 2, above the growth body 3, so that a further CSV degradation, a further nitration and an aerobic breakdown of the sludge that forms are carried out. Through the retrofitted opening Ö flows, as already explained with reference to Figure 1, due to the function of the pump device 4, d. H. the extraction of unpurified wastewater from chamber 1, exhausted, cleaned wastewater from chamber 2 back into chamber 1 and overlaid the settled solids F and the lower area of the liquid part of the wastewater A. This overlay prevents or prevents odor nuisance from the overlaid layers the superimposed area is also enriched with oxygen, so that here too. T. aerobic degradation of the dirt load can take place. At the same time, the intermittent operation of the pumping devices ensures that the oxygen content of the liquid layer and that of the wastewater emptied temporarily decrease and that nitrate ions which are produced are denitrified.

FIG. 3 finally shows the sequence of the method according to the invention on the basis of a flow diagram. The flow diagram shown in FIG. 3 makes the basic principle of the process clear: after the inflow Z of the waste water, it can settle the heavier solid components in chamber 1. A first pumping device 4 brings wastewater that is largely freed from solid components, but is otherwise unpurified, into chamber 2, in which the growth bodies 3, which are colonized by bacteria, are arranged. The first pump means 4 can be ^'the waste water through the air above the free falling growth body 3 in the chamber 2 to flow. As a result, the wastewater is enriched with atmospheric oxygen, which enables the bacterial degradation of the organic dirt load (CSV) and nitration. By drawing off waste water by means of the pump device 4 from chamber 1, emptied, cleaned waste water flows out of chamber 2 through the opening Ö back into the upper region of chamber 1 and overlays the lower region of chamber 1, ie the solid, heavier substances deposited there and the lower part of the liquid wastewater located there. This overlay prevents odor nuisance from escaping from chamber 1 and also ensures a partial aerobic degradation of the solid components stored there, while nitrate formed is denitrified when the pumping devices are interrupted. The pump device 7 leads wastewater and biorases dropped from the growth bodies 3 from the bottom of the chamber 2 to the top of the growth bodies 3 again, which leads to further oxygen input and further degradation of the organic contents of the wastewater. The cleaned excess of the waste water flows through the outlet 6 and is introduced into water or into the ground.

The remaining sludge remaining in chamber 1 is removed and removed at large intervals (e.g. once a year).

Claims

claims

Process for wastewater treatment in small sewage treatment plants with at least two chambers (1, 2), in which wastewater (A) is introduced into the first chamber (1), in which heavier solids (F) settle on the floor and a liquid part (L) of the wastewater into the further chamber

(2) is passed on ", in which growth body (3) are arranged for colonization with bacteria and an aerobic degradation of the remaining ingredients of the wastewater takes place and an exhausted, cleaned water body (W) is formed, characterized in that by suctioning off the liquid part (L) of the waste water (A) by means of a first pump device (4) from a location of an upper layer area (5) in the first chamber (1) to a location above the growth bodies

(3) in a subsequent chamber (2) a part of the emptied, cleaned water body (W) flows back through one or more opening (s) (ö) into the upper region of the first chamber (1), whereby the lower, liquid only partially the aerobic area (L) of the waste water (A) is overlaid by the aerobic upper layer area (5) and the area below is diluted with drained, purified water; that the biorases falling off the growth bodies (3) by suctioning off the water layer present under the growth bodies (3) the growth bodies (3) by means of a second pumping device (7) from the top and from outside of the standing liquid is again supplied, the operation of the Pumping devices (4, 7) are program-controlled with interruptions and when the operation is interrupted, the oxygen content of the liquid layer and that of the emptied water body decreases and nitrate ions formed are denitrified; that the excess part of the emptied cleaned water body (W) through the outlet (6) arranged in the upper region of the second chamber (2) is diverted; and that aerobic or anaerobic solids (F) that cannot be further degraded are removed from the first chamber (1) and removed.

2. The method according to claim 1, characterized in that the pumping devices (4, 7) let out the liquids above the chamber (s) (2) and the required liquid in the free jet into "the m of the second chamber (s) (n ) (2) liquid is entering.

3. The method according to claim 1 and / or 2, characterized in that the program-controlled interrupted operation of the pumping devices (4,7) is carried out by time control.

4. The method according to claim 1 and / or 2, characterized in that the program-controlled interrupted operation of the pumping devices (4, 7) m is dependent on the oxygen concentration of the liquid part (L).

5. The method according to one or more of the preceding claims, characterized in that the liquids are pumped by means of submersible pumps.

6. The method according to claim 5, characterized in that the submersible pumps (4, 7) are electrically driven and are operated partially or exclusively with solar energy.

7. The method according to at least one of the preceding claims, characterized in that the emptied water when flowing back m the first chamber (1) by upward arrangement of the openings (ό) or by baffles, the heavier solids and the surrounding liquids in the first Chamber (1) overlaid without cross flow.