NL8204569A - Device for the treatment of waste water, in particular communal waste water. - Google Patents

Description

- 1 - N / 31.137-Kp / Pf / cs

Wastewater treatment plant, in particular communal wastewater.

The invention relates to an installation for the purification of waste water, with grate, aerated sand trap, adsorption stage, experience stage and explanation, in which in the adsorption stage mainly an adsorption and flocculation of high molecular compounds takes place and this via an intermediate clearance as sludge from the can be extracted from the adsorption stage, in the experience stage mainly a degradation of the residual compounds takes place, while the purified waste water can be extracted via the declaration and a sludge return between the adsorption stage and the experience stage is not regulated. Within the scope of the invention, stair means conventional structures in the field of wastewater engineering, which in turn can be divided into several units. In the adsorption stage, adsorption and flocculation occur next to a biodegradation.

In the known device of the indicated type (published German patent application 26 40 875), the first experience stage is driven with a sludge load of at least 2 kg BOD2 per kilogram of dry matter and day, and the amount of excess sludge withdrawn from the intermediate clearance results in the sludge in the first experience stage held in that exposure phase, in which substrate breathing starts. For the rest, a strict separation of the biocoenosis of the two stages is ensured. The sludge from the second with a sludge load of 0.15 BODg per kilogram of dry matter and day-driven experience stage is removed directly from the sludge cycle without recycling. In the adsorption stage, anaerobically is mainly optionally worked. However, the adsorption stage can also be aerobically floatable. All this is a method of construction and operation which has been tried and tested in particular for large ready-to-use equipment, but requires the usual sludge treatment for the intermediate clearance reap, from the second experience 8204569 - 2 - * stage resp. sludge removed from the declaration.

On the other hand, the object of the invention is to further design the device as described in the preamble in such a way that such a sludge treatment is no longer required. Devices according to the invention are in particular for connection values up to 50,000 residents or. population equivalents.

In order to solve this problem, the invention teaches that the experience stage is designed as a basin aeration stage, in which the sludge can be led from an adsorption preliminary stage as well as from the absorption stage and in which these sludges and the sludge formed in the basin aeration stage can be deposited. and it can be stabilized that the adsorption stage is arranged between the grating and the adsorption stage, which optionally can be driven aerobically, that the adsorption stage can be aerobically driven, and that a moist biotope is connected after the basin aeration stage. The formulation that the adsorption stage is optionally floatable anaerobically does not preclude it from being aerobically floated if necessary. The basin aeration stage may consist of one or more units. A preferred embodiment of the invention is characterized in that the aerated sand trap is also set up as an adsorption stage, so that special construction costs are not required in this respect. A rough clearance can be arranged between adsorption advance stage and adsorption stage 25.

Within the scope of the invention, basin aerator means a conventional basin aerator known per se with two or more aeration basins. Typical for classic basin aerators with two aeration basins and a clarifier basin is a specific space requirement of a little more than 3 m per inhabitant respectively. in-residence equivalent and a specific surface requirement of just over 2 nr * per inhabitant resp. population equivalent. The space load of the aeration basins is 30 g BOD ^ / m .d.

35 The usual basin aeration connection values are a maximum of approx. 8,000-10,000 inhabitants resp. population equivalents. Several hundred classic basin aerators have been installed in the Federal Republic of Germany. These comply with the existing regulations and the desired decomposing power and have proven their value in this respect. They have a high process stability and are considered to be close to nature devices. Although they require a large specific surface and space requirement on the one hand, they are, on the other hand, virtually maintenance free. The investment cost per inhabitant or inhabitant equivalent is very small. The advantageous construction as well as the low-maintenance exploitable can be traced back, inter alia, to the fact that such basin aerating devices could generally be set up by means of earth construction and that due to the high space and surface area, special devices in the form of sand collector, grate and sludge treatment devices are unnecessary. Residence time of the wastewater to be purified in the aeration basins is in the range of 10-15 days. The specific energy consumption per kilogram of broken BOD5 is approximately 1 kWh / kg BOD5, and thus corresponds to the use of oxidation channels. As stated, the high space available allows such basin aeration devices to be operated without grids, without a sand collector and without a special sludge treatment step. The sludge is deposited on the bottom of the aeration basins. The continuously aerated and agitated water flows over the sludge and supplies the upper sludge layer with oxygen, so that the sludge does not float and does not rot in the top layer. The deeper sludge is broken down anaerobically. Only after years it is necessary to pump out the fully stabilized sludge. The waste water itself is purified in the aerated baiisins via very fine flakes floating in the water and via the aerators attached to the bottom.

According to the invention, a basin aeration device in its basin aeration stage fulfills a new function: The sludge otherwise to be fed to the sludge treatment in the known devices is deposited and stabilized in the aeration basin or in the aeration basins of the basin aeration stage. This is successful because of the combination with the other building elements and measures of the device according to the invention, namely because of the combination with the adsorption pre-stage, which optionally anaerobic resp. works aerobically, with the adsorption stage active in the aerobic region, as well as with the downstream moist biotope, in which a further purification of the waste water is carried out. Existing basin aeration devices 8204569-4 directions can be converted into devices according to the invention without great expense and operated with considerably higher connection values.

Within the scope of the invention, the adsorption stage 5 can be designed as an immersion body stage. A preferred embodiment of the invention is further characterized in that the adsorption stage as a heavily loaded stage with BDg = 2, preferably about 5, the adsorption stage also as a heavily loaded stage with BDg = 2, at Preferably approx. 3 / has been carried out and that the basin aeration stage acts as a slightly loaded stage. In general, in an apparatus according to the invention, the basin aeration stage has two aeration tanks connected in series, the first of which can be driven with a BDg of about 0.3, and the second with a BDg of about 0.05. A device for the addition of a precipitant may be arranged for the adsorption stage and / or for the first of the aeration basins.

In comparison with the known embodiment, in the device according to the invention, the downstream basin aeration stage with subsequent moist biotope has arisen from the, as it were, conventional experience stage. The adsorption stage can be interpreted, as it were, as a special partially biologically coarse clarification and makes from the conventional aerated sand collector its own adsorption stage, which, however, can optionally be anaerobically or aerobically driven within the scope of the invention, while the hitherto Although the adsorption stage used is retained, it is aerobically driven. She receives the well-worked-up substrate, which is readily biodegradable in the adsorption stage. One might have the impression that the device according to the invention is cumbersome due to the high degree of division. However, this is not the case, since in the context of the combination according to the invention the separate units require little space and the processes run stably and are easy to control. The subsequent basin aeration stage requires virtually no maintenance work, although fine cleaning and sludge treatment occurs over the years due to sludge accumulation in these basins. As a result, according to the invention, also in comparison with the conventional basin aeration, substantial 8204569 ------ · · - · '- ·. --.- <jp '- 5 - benefits achieved. Compared to conventional basins aeration, the specific surface requirement is considerably reduced by increasing the waste water volume flow. The combination retains the advantages of the basin aeration, that is to say sludge treatment and stabilization as well as sludge accumulation take place in the aerated basins, but also in the downstream settlement as well as in the moist biotope. A high degree of stabilization of the sludge is achieved in the basins, the degree of stabilization being a direct function of the residence time. For the rest, the device according to the invention excels through high process stability and high degree of purification. This is achieved by the succession of four different biotopes, each of which exhibits its own biocoenosis (optional an-15 aerobic, aerobic, aerobic, biotope). The two stages, i.e. the adsorption stage as well as the basin aeration stage, are indeed both aerobic stages, but they do have different biocoenosis. As mentioned, the heavily loaded steps (optionally anaerobic, aerobic) provide access to difficultly degradable organic materials. This creates an easily degradable substrate for the subsequent basin aeration. As indicated, find an addition of precipitants (e.g. of Fe (II) salt) for the adsorption stage and optionally also for the adsorption stage or. before the first aeration basin, this leads to a far-reaching elimination of phosphate, which is additionally enhanced by the moist biotope, with subsequent long residence times in the basin aeration stage. The advance of the two heavily loaded stages reduces the surface requirement of the basin aeration by 70% compared to a conventional, aerated basin device and allows an increase of the waste water flow to at least three times. The activation of an immersion body, which can be used in the context of the invention as described, further contributes to minimizing the specific energy requirement.

The invention will be elucidated hereinbelow with reference to a drawing illustrating only one exemplary embodiment:

The figure shows the scheme of a device according to the invention.

82 «45 69.

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The device shown in the figure is intended for the purification of waste water, in particular for the purification of communal waste water. The device includes a grid 0, an aerated sand trap 1, an adsorption stage 2, 5, an experience stage 3, an explanation 4. In the adsorption stage 2, in addition to a biodegradation, mainly an absorption and flocculation of high molecular compounds takes place. These are removed with the sludge from the adsorption stage 2 via an intermediate ring 5 from the adsorption stage 2. In the experience stage 103, mainly a breakdown of the residual compounds takes place. The treated wastewater can be removed via statement 4.

Sludge recycling between the adsorption stage 2 and the experience stage 3 does not take place in order to severely separate the biocoenosis of these experience stages 2/3.

The experience stage is in the form of a basin aeration stage 3, in which the sludge can be led from an adsorption pre-stage 1 and the adsorption stage 2 and in which these sludges and the sludge formed in the basin aeration stage 3 can be deposited and stabilized. Between the grating 0 and the adsorption stage 2 is the adsorption pre-stage 1. It is optionally operable anaerobically (but also aerobically), while the adsorption stage 2 can be aerobically driven. In the exemplary embodiment and according to the preferred embodiment of the invention, the aerated sand collector 1 is designed in the form of an adsorption stage. A coarse clearance 6 is interposed between adsorption stage 1 and adsorption stage 2. A moist biotope 7 is connected behind the basin aeration stage 3.

It has not been shown that the adsorption stage 2 can be in the form of an immersion body stage. The adsorption stage 6 is in the form of a heavily loaded stage with BDg = 2, preferably about 5 / the adsorption stage 2 is also designed as a heavily loaded stage with BDg = 2, preferably about 3. The basin aeration stage 3, on the other hand, functions as a weakly loaded stage. In the exemplary embodiment and according to the preferred embodiment of the invention, it has two successively connected aeration basins 3a, 3b, the first of which can be made with a BDg of about 0.30 and the second with a Bg of approximately 0.05. driven. For adsorption stage 1 and / 8204569 - - ,, - v- "-i -. ·. £: if, * 'rr - 7 - or for the first aeration basin 3a, a device 8 for the addition of a Moreover, such a device 8 could also be provided before the adsorption stage 2.

5 An establishment for a connection size of 12,000 affiliated inhabitants and population equivalents is described. The waste water has a communal industrial character. The device has such dimensions that it can easily reach 100,000 to 24,000 inhabitants, respectively. resident equivalents 10 can be expanded. An area of up to 25,000 m2 is available. In the new building, the installation is designed for a drop flow supply QDW = 192 m / h, during rainy weather the quadruple QDW quantity flows to the installation. Up to the twofold QDW ~ 15 amount, the wastewater goes through other purification steps. Mixing rain water in an amount of 2 QDW is fed directly to the aerated basins (3) and also biologically purified. The device shows the deductions, taxes and effects listed in the table below. The daily waste water flow turns out to be 200 1 waste water / inhabitant and day, which corresponds. with a waste water flow QQW = 3,000 m ^ / d.

82 OM S 6 8 3 9 - 8 -

Table

Adsorption- Adsorption- Basin aeration- Wet pre-stage trap tingstrap biotope

SP R BZ GV A TK B B N VB

F_: 8 16 10 16 450 300 360 320 S________ 5 VG: 96 192 120 192 9,000 4,350 3,800 '-v ---- sV- “' 600.nT 17,150 m5 t: 0.5 1 0.6 1 72 35 30 h W ": 7,500 3,600 24 ^" R ______ B: ^ 5 ^ 3 ^ 0.3 0.05 D b _______ 10 η: 40 50 85 50% BODj-: 240 144 72 11 = 10 V "= 1 /inw.xd, V „= m ~, B_ = g BODc / m ^ .d, SGR 5 BDS = kg BOD5 / k9 DS.m3.d, B0D5 (Mi) = m9 / l SP = screw pump- GV = coarse front B = basin arrangement clearance 15 R = grille A = adsorption stage N = clearance BZ = bel.sand trap TK = intermediate clearance VB = moist biotope

The waste water flow QDW is introduced into the installation via a screw pump device and passes through the grate 0. After screening of coarser constituents, the coarsely mechanically treated waste water flows into the aerated sand trap 1, which is recycled from the coarse clarification by returning the biologically activated sludge. 6 simultaneously performs the function of an adsorption stage via a return line. This adsorption stage 6 is heavily loaded with a sludge load of 25 Bds = 5 kg / BOD ^ / kg DS and a dry matter content of DS = 1.5 kg DS / m3.d driven. The purified water in the coarse clarification of substances to be deposited flows to the adsorption stage 2 which is designed in the form of an immersion body. The substrate that flows to this biological adsorption stage 2 is readily degradable and is partially biologically purified in the immersion body at a residence time of t = 38 min with a sludge load BDg = 3 to 50%. The biologically activated sludge formed from this adsorption stage 2 is deposited in the intermediate clearance 8204569 .........: - - - - 9 - and is recycled to the adsorption stage 2. The excess sludge from the sand collector 1 and the adsorption stage 2 passes through an excess sludge to the aeration basins 3a, 3b and is deposited there 5 and stabilized.

In the two heavily loaded partially biological stages, namely the adsorption pre-stage 1 and the adsorption stage 2 designed as land catcher, a large part of the organic load is already broken down. This portion 10 is up to 40% in the adsorption stage and 0.50 in the adsorption stage. 60 = 30%, so total up to 70% of the initial load.

After this considerable reduction of the load 15, the experience stage 3 has certain dimensions according to the known rules of the art. Compared to the conventional basin aeration process, the same size criteria (= 30 g BOD / m) are used, which results in an area of approximately 3% reduction in the experience stage 3. Thus, the waste water flow (m 3 / h) fed through the aeration basins 3a, 3b is increased by more than three times as compared to a conventional pure basins aerator. After the biological purification in the aeration basins 3a, 3b, the waste water flows into the declaration 4 and is fed from this via discharge shafts to the moist biotope 7. With the residence time used here of more than 1 day and the strong plant growth present in the flat design of the moist biotope 7 of 70 cm, a further purification of the waste water takes place.

Due to the illustrated extension of the partially biological steps 1, 6, 2, 5, the device can achieve a connection size of 24,000 in / ineq with the same effect. can be expanded without a larger surface requirement.

As already described, the highly organic activated sludge precipitated in the two biological stages, adsorption stage 1 and adsorption stage 2 is fed to the experience stage 3, deposited here and largely stabilized.

Over periods of 1 year, the first aeration basin 3a and over periods of 2 years each, the second 40 aeration basin 3b must be removed from the stabilized sludge. 820416¾ 1 »- 10 -. The deposited and stabilized sludge is pumped out of the basins. In that case, the sludge waste water flow runs via a sludge thickener that is in continuous operation. Here a separation of the solid and the liquid phase occurs.

The contaminated water is returned to the supply of the device and goes through all biological steps. The daily additional flow of contaminated water during the 10-day pumping-off season per year at 3 500 m and korat corresponds to only 1/6 of the daily waste water flow and can pass through the installation without difficulty through both the amount of waste water and since the multistage biological system exhibits an exceptionally high buffer capacity with respect to quantitative and qualitative load peaks.

The thickened sludge (= solid phase) is extracted from the sludge thickener and thickened via a sludge centrifuge, which is installed in a commercial building. The dewatered and largely stabilized sludge is either used in agriculture or removed for dumping.

When a particularly high degree of far-reaching purification of the waste water to be processed, for instance with regard to a phosphate elimination or an elimination of difficultly degradable substances (CSB) is required, precipitants for the adsorption stage 1 at 8 and for the first aerated basin added at 8, preferably for the sand trap 1 lime or aluminum sulphate and for the aeration basin 3a iron (II) salts. Such a combination requires little use of precipitants and minimizes the addition of iron salt. This method of adding precipitants, for example, lowers the phosphate content of communal industrial wastewater to concentrations below 0.5 mg P / l. Algae growth is reduced and the formation of algae is considerably reduced via the moist biotope 7.

35 8204569

Claims (7)

1. Device for the purification of waste water, with grate, aerated sand trap, adsorption stage, 5. experience stage and explanation, whereby in the adsorption stage mainly an adsorption and flocculation of high-molecular compounds take place and these can be removed from the adsorption stage as intermediate sludge. be removed, whereby in the experience stage mainly a degradation of the remaining compounds takes place, while the purified water can be removed via the declaration and a sludge return between the adsorption stage and the experience stage is not arranged, characterized in that the experience stage is in the form of a basin aeration stage (3), in which the sludge from an adsorption stage (1) as well as the adsorption stage (2) can be guided and in which these sludges and the sludge formed in the basin aeration stage can be deposited and stabilized, that the adsorption pre-stage (1) is arranged between grid (0) and adsorption stage (2) d, which can optionally be driven anaerobically, that the adsorption stage (2) can be aerobically driven, and that a moist biotope (7) is connected after the basin aeration stage (3). Device according to claim 1, characterized in that the aerated sand trap is designed as an adsorption stage (1). A seal according to any one of claims 1 or 2, characterized in that a coarse clearance (6) is arranged between adsorption stage (1) and adsorption stage (2). Device according to any one of claims 1 to 3, characterized in that the adsorption stage (2) is in the form of an immersion body stage. 5. Device according to any one of claims 1-3, characterized in that the adsorption stage (1) as a heavily loaded stage with B 2, preferably about 5, the adsorption stage (2) also as heavily loaded stage with BDg = 2, preferably about 3, and that the basin aeration stage (3) acts as a weakly loaded stage. 8204569 '- 12 - Device according to any one of claims 1 to 5, characterized in that the basin aeration stage (3) has at least two aeration basins (3a, 3b) connected one behind the other, the first of which having a BDg of approx. 0.3 and 5. the second can be driven with a Bg of about 0.05. Device according to any one of claims 1 to 5, characterized in that a device (8) for the addition of a precipitant is arranged for the adsorption stage (1) and / or for the first of the aeration basins (a). 10 8204569