NL8204025A - METHOD FOR OPERATING A BASIN VENTILATION EQUIPMENT, AND BASIN VENTILATION DEVICE - Google Patents

Description

N / 31.138-K £> / Pf / vdM · «h - 1 -

A method for operating a basin aerator, as well as a basin aerator.

The invention relates to a method for operating a basin aerator with aeration basin, an upstream drip body arrangement and an after-flow basin, which basin aeration unit 5 installed or to be installed aeration basins with predetermined basin aeration size and predetermined basin aeration connection values (inhabitants or inhabitants) 10 is thus calculated for a predetermined basin aeration waste water quantity flow in cubic meters and days. In general, two aeration basins are connected one behind the other. The invention further relates to a basin aerating device for carrying out such a method. In the context of the invention, waste water means in particular communal or comparable readily degradable waste water. The concepts of basin aeration size and basin aeration connection values derive from the prevailing theory of basin aeration devices. Typical for classic basin aerators with two aeration basins and a clarifier basin is a specific space requirement of 20 over 3 m per cubic meter, resp. inhabitant equivalent 2 and a specific surface requirement of just over 2 m per inhabitant, resp. resident equivalent. The space load of the aeration basin is 30 g BOD ^ / m · d. The usual basin aeration connection values are 8,000 to 25 maximum 10,000 inhabitants, respectively. resident equivalents.

Within the framework of the measures (known from practice), the droplet body device is operated as a weakly loaded device with a space load of the order of 1-2 kg BODg / m 2 · d, and via the weakly loaded droplet body device thus operated the Conventional basin aeration waste water mass flow corresponding to the connected load is supplied to the aeration basins. This can be achieved without difficulty up to the stated connection values of 8,000 to a maximum of 10,000 inhabitants or population equivalents. With higher connection values, the 8204025 1 * - 2 surface requirement and the space requirement become too high. This applies both to basin aeration devices with so-called compressed air candles generally fixed in the center of the aeration basin, as well as to basin aeration devices with generally compressed air candles hanging in the aeration basin and swinging back and forth on the fronts of the aeration basins. . With regard to the theme of wastewater treatment, in particular cleaning of municipal wastewater using basin aeration devices, the following can be noted in more detail:

Several hundred classical basin aerators have been installed in the Federal Republic of Germany. They meet the existing regulations and the desired breaking capacities and have complied to that extent.

They have a high process stability and are considered to be close to nature. On the one hand they require a high specific surface and space requirement, but on the other hand they require very little maintenance. The investment costs per inhabitant or inhabitant equivalent are very low. The inexpensive construction as well as the low-maintenance operation can be explained, among other things, by the fact that such basin aeration devices can generally be set up using soil construction and that, because of the high space and surface area, special devices in the form sand traps, grates and sludge treatment devices are unnecessary. The residence time of the waste water to be purified in the aeration basins is in the range of 10-15 days. The specific energy consumption per kilogram of broken BOD ^ is approximately 1 kWh / kg BODj. and thus corresponds to the consumption of oxidation channels. The high space available makes it possible, as mentioned, to operate such basin aerators without grids, without a sand collector and without special sludge treatment steps. The sludge is deposited on the bottom of the aeration basin. The continuously aerated and agitated water flows over the sludge and oxygenates the top layer of the sludge so that the sludge does not float up and rot in the top layer. The lower sludge is broken down 8204025 - 3 - * * anaerobically. Only after years is it necessary to pump out the fully stabilized sludge. The waste water itself is purified in the aerated basins via very fine flakes floating in the water, as well as via the aerators attached to the bodeia.

The object of the invention is to propose a method by means of which it is possible to exploit a connection aerator with increased connection values compared to the conventional connection terminal connection values and thus with a considerably increased waste water mass flow. The object of the invention is furthermore to provide a basin aerator suitable for carrying out such a method.

As a solution to this problem, the invention teaches that the dropping body device as a highly loaded device with a space load in the range of 2-12 kg BOD, - / 3 3 bm · d, preferably about 5 kg BOD ^ / m · D, is adjusted and operated and that a waste water mass flow is supplied via the heavily loaded droplet body device thus operated to the (unchanged) aeration basins, which is at least a factor 1.5 greater than the conventional basin aeration waste water mass flow. For the rest, however, the aeration basins are further exploited in a classic manner.

25 The sludge settles on the bottom of the aerated basin as before. 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 upwards and does not rot as before. Only after years it is necessary to pump out the fully stabilized sludge. The waste water itself is purified in the aeration basins via very fine flakes floating in the water, as well as via the aerators mounted on the bottom. The invention thus combines a drip body device designed as a highly loaded device with 35 aeration basins of a classic basin aeration device that are not or not significantly altered in terms of construction and thus provide the possibility to expose the device as a whole with connection values, which is a factor of at least 8204025 «- 4 - 1.5 or even 2 to 3 higher than that of a conventional basin aerator. The invention is therefore particularly important when it comes to setting up or converting an existing basin aeration device for these increased connection values, or in other words for an increased waste water mass flow. To that end, only the exchange of the droplet body device or its construction is necessary. However, the invention is not exclusively important for the conversion of existing basin aeration devices. The teaching of the invention relates much more also to newly built basin aeration devices, in which the drip body arrangement is then arranged and operated as described, while the aeration basins are, as it were, classic.

In more detail, there are various possibilities for further elaboration within the scope of the invention. In the embodiment for a basin aerator with coarse pre-device connected upstream of the drip-body device, the invention teaches that the coarse pre-clearance 20 is carried out in a transverse flow-through round basin, wherein sand and coarse sludge settle and that the sand and coarse sludge pass underneath. from the dropper body device from the coarse clarifier to the aeration pools and deposit there. According to a preferred embodiment of the invention, the drip body device is operated at a rinsing speed of 5 m / h and more and so-called biological sods formed in the drip body device are washed away and also deposited in the aeration basin.

An embodiment of the invention, which has special and independent significance, concerns measures which make it possible to operate a classically designed and operated basin aerator with a waste water mass flow, which is a factor 2 or more larger than the classic basin aeration waste water mass flow. . To this end, the invention teaches that an equally heavily loaded adsorption basin is arranged between the heavily loaded droplet body device and the aeration basins and that the sludge from the adsorption basin is also introduced into the aeration basins and deposited there. -Adsorption basin means an experience basin for the adsorptive, self-filtering and coagulating removal of relatively difficult-to-degrade carbon and nitrogen compounds, which is aerated with ambient air and as very heavily loaded experience basin 3 with a space load of approx. 10 kg BOD ^ / m · d and exploited with a sludge load of at least 2 kg BOD ^ / kg DS * d is exploited (cf. German Auslegeschrifts 2,640,875 and 2,803,759).

It is within the scope of the invention to add flocculants between the first and the second highly loaded biological stage. On the one hand, the purification capacity of the stimulation stage is thereby increased, and on the other hand the phosphate content is bound and deposited with the sludge in the aeration basins. Together with the phosphate reduction in the following basin aeration steps and in the humid biotope, phosphate reductions of 80-90% are thus achieved. Within the scope of the invention it is furthermore between the first and the second aeration basin to add flocculants, eg Fe (II) salts. Within the scope of the invention it is furthermore to pass the purified waste water from the clarifying basin into a moist biotope and to further purify therein.

Also in the method according to the invention the aeration basins of the basin aerator operate with their specific process stability. As before, special sludge treatment steps are not required and grids etc. are also unnecessary. However, the space or surface requirement is considerably reduced to 1/4.

In other words, the waste water mass flow can thus be increased accordingly. The basin aeration system, which is close to nature, can be used for considerably higher connection values, namely for connection values up to 30,000-40,000 inhabitants, respectively. resident equivalents are applied.

Both the drip body arrangement and the adsorption basin 35 require little maintenance. The heavily loaded stimulation can be aerated by means of compressed air or surface aeration, preferably the aeration takes place via compressed air, which can be done via connections to the air compressors already present 8204025-6 - of the basin aerator. In the pre-adsorbed basin embodiment, some of the more readily degradable organic compounds in the drip body arrangement are degraded with very low specific energy consumption of 0.25-0.30 kWh / kg BOD, ed. the adsorption basin which can be exploited optionally anaerobically as well as aerobically, preferably, however, optionally anaerobically, whereby the difficult-to-degrade substances are converted into readily degradable substances. These residual substances can be broken down in the aeration basins. The energy consumption is reduced by about 50% compared to the conventional aeration basins. With a given waste water mass flow, the investment costs are considerably lower, namely reduced by about 30-40%.

The method according to the invention is described below and the basin aerating devices arranged for this method are further elucidated with reference to a drawing.

Figure 1 is a schematic diagram of a basin aerator with a highly loaded drip body arrangement arranged for the method according to the invention.

Figure 2 is a schematic diagram of a basin aerator 25 equipped for the method according to the invention with a heavily loaded droplet body device and adsorption basin.

The device shown in Figure 1 is a basin aeration device with two aeration basins 1, 2, an upstream drip body device 3 and an off-set basin 4. The basin aeration device has aeration basins 1,2 with predetermined basin aeration size and predetermined basin aeration connection value (inhabitants or inhabitant equivalents) . This means the values elucidated in the introduction which, according to classical teaching, can be maintained for such aeration basins. In other words, this means that the aeration basins 1,2 are calculated on a predetermined basin aeration waste water mass flow in cubic meters and days. The drip-body device 3 is, however, not as a weakly loaded device, but rather as a strongly protected 8204025 * -: -: --...

- 7 - Loaded installation with a space load in the range of 3 2-12 kg BODg / m · d. The installation of the entire installation is aimed at a waste water mass flow that is at least a factor 1.5 greater than the conventional waste water-5 mass flow, on which the aeration basins 1, 2 are set up per se. The drip-body device 3 can be constructed with plastic-drip-body material and be designed in such a way that it can be freed from biological turf by a rinsing speed of 5 m / h and more. Furthermore, a coarse pre-clarifying device 5 is connected upstream. The swelling is such that the sand and coarse sludge from the coarse pre-preparation device 5 can be inserted into the aeration basins 1, 2 by means of a mammoth pump, which is connected to the aeration device 5 of the aeration basins 1, 2. lined.

The aeration device 6 is constructed in a classical manner and is also adjusted to the classical basin aeration waste water mass flow.

Figure 2 shows the embodiment with an adsorption basin 7 arranged between highly loaded drip body device 3 and aeration basins 1, 2, wherein the aeration installation of the adsorption basin 7 is also connected to the aeration device 6 of the aeration basins and the sludge from the adsorption basin 7 in the aeration basins 1, 2 can be fed.

In the embodiment according to Figure 1, the upstream heavily loaded drip body device 3 achieves that already for the aerated basins 1, 2, approximately 30-50% of the dissolved organic substances in the waste water are converted into solid deposits. When the drip body device 3 operates with the indicated space load, this breaking capacity is achieved without difficulty. As a result, with 170 m volume for coarse clarification and drip bead 3, more than 12,000 m 2 of basin volume can be saved. This means that for a municipality with a connection size of 12,000 inhabitants, resp. population equivalents, only the same surface area requirement is required as for a basin aeration system for 6,000 residents or population equivalents.

8204025 - 8 -

According to the invention, a conventional biological stage is connected with the drop body device 3, which, however, in a special way, i.e. is operated as a heavily loaded device. Otherwise, the sludge formed from this biological step is not treated as is customary with biological steps. The sludge is fed much more into the aeration basins 1, 2 and deposits there. The continuously aerated and agitated water flows over this sludge and supplies the upper sludge-10 with oxygen, so that the sludge does not float upwards and does not rot in the upper area. Only after years, as before, is it necessary to pump out the fully stabilized sludge. The waste water is then purified in the aeration basins 1, 2 as before via very fine flakes floating in the water, as well as via the aerators attached to the bottom. In the embodiment with upstream coarse pre-clarifying device 5, the functions of a grate, of a sand catcher and of a coarse pre-clarification are combined effectively by means of a transversely flow-through round basin, or also by a longitudinal pre-clear basin. The floating components are retained in the rough clearance 5 and are forced to sink by continuous weak aeration. The sand and the coarse sludge, preferably via a mammoth pump, get into the drain of the droplet body and thus into the aeration basins 1, 2. However, this also applies to the biological sods, which are flushed into the droplet stage 3 by high rinsing speed. washed away. These are deposited in the aeration basins 1, 2. The energy costs are considerably reduced, since half of the load is broken off via the heavily loaded dropper body device 3. For example, with a 4 m high drip body arrangement, the specific energy consumption is 0.25 kwh / kg BOD ^ ed. Compared to the pure basin aerators with a specific energy consumption of 1.0 kWh / kg BOD ^ ed., An energy saving of about 35% obtained.

In addition, in the embodiment according to Figure 2, the highly loaded adsorption basin 7 is provided, in particular arranged between the drip body device 3 and aeration basins 1,2. As a result, the connection size 8204025 ψ- '- 9 - can be widened again, without the specific surface requirement and space requirement having to be disruptively increased. Rather, the specific space requirement can be reduced by interconnection of such an adsorption basin. By connecting the two highly loaded biological stages, i.e. the drop body device 3 and the adsorption basin 7, about 75% of the organic load can be removed before the aeration basins 1, 2, so that they only need about 25% of the 10 otherwise required size, in other words, at least with a factor 3 higher wastewater mass flow can be exploited. Quite surprisingly, for the aerated basins no substances that are difficult to degradate remain, which could not or could not be sufficiently processed there: in the heavily loaded droplet body device 3, n. about 50% of the organic load is broken down.

In the highly loaded adsorption stage 7, which is preferably optionally operated anaerobically, the materials which are difficult to degrade are converted into more easily degradable compounds. Accordingly, the stream from the highly loaded adsorption stage 7 is readily biodegradable. This is purified completely satisfactorily with 20-30 g BODg / m 2 · d under the usual space load of the aeration basins 1,2. For the rest, an after-drying period of 1 day 25 is sufficient for this treatment to obtain values of 15 mg BOD 2/1 for the outflowing water when treating communally or similarly degradable waste water. These values meet the requirements of the new legislation in this area.

30 8204025

Claims (11)

Method for operating a basin aerator with aeration basins, an upstream drip body arrangement and a clear basin, which basin aerator installed or to be installed aeration basins with predetermined basin aeration size and predetermined basin aeration connection values (inhabitants or inhabitant equivalents) it is thus calculated for a predetermined basin aeration waste water mass flow 10 (in cubic meters and days), characterized in that the drip body device as a highly loaded device with a space load in the range of 3 3 2-12 kg BOD ^ / m · d, preferably 5 kg BOD / m * d, is equipped and operated and that a waste water mass flow, which is at least a factor 1.5 greater than the basin aeration waste water mass flow, is supplied via the heavily loaded drip body device thus operated to the aeration basins . 2. Method as claimed in claim 1, in the embodiment with coarse pre-clarifying device connected upstream to the drip-body device, characterized in that the coarse clarification in a transverse flow-through round basin, respectively. is carried out in a longitudinal basin, with sand and coarse sludge depositing and the sand and coarse sludge passing from the coarse pre-clarifier passing the drip body assembly to the aeration basins and depositing there. Method according to either of Claims 1 and 2, characterized in that the drip body device is operated at a rinsing speed of 5 m / h or more, and biological sods formed in the drip body device are flushed out and also to the aeration basins be fed and deposited there. Method according to one of Claims 1 to 3, 35, characterized in that an equally heavily loaded adsorption basin is arranged between the heavily loaded drip body device and the aeration basins and that the sludge from the adsorption basin is also sent to the aeration basins 8204025 * 9 - 11 -. supplied and deposited there. 4 · "- 10 - 5. Process according to any one of claims 1-4, characterized in that precipitants, eg Fe (II) salts, are added before the first aeration basin. A method according to any one of claims 1 to 5, characterized in that the purified waste water from the clarification basin is led into a moist biotope and further purified therein. A method according to any one of claims 1-6, characterized in that precipitants, e.g. Fe (II) salts, are added between the first heavily loaded dropper stage and the second heavily loaded bubble stage. 8. Device for carrying out the method as claimed in any of the claims 1-7 - with aeration basins, upstream drip body device and aftercutting basin, characterized in that the drip body device as a highly loaded device with a space load in the range of 8-12 BODg / m ^ * d has been carried out and that the installation of the entire device is aimed at a mass flow, which is at least a factor 1.5 greater than the basin aeration waste water mass flow, for which the classically sized aeration basins have been calculated. Device according to claim 8, characterized in that the drip body device is constructed with plastic drip body material and is freed from biological turf by a rinsing speed of 5 m / h or more. Device according to either of Claims 8 or 9, with upstream coarse pre-clarifying device, in which sand and coarse sludge deposit, characterized in that the sand and coarse sludge form the coarse pre-clarifying device by means of a mammoth pump connected to the - 35 ventilation device can be fed from the aeration basins to the aeration basins. 11. Device as claimed in any of the claims 8-10, in the embodiment with intermediate adsorption basin, 8204025 5-12 - characterized in that the aeration installation of the adsorption basin is connected to the aeration device of the aeration basins. 8204025