DE2910015C2 - Process for the oxygenation of a waste water / activated sludge mixture and for the denitrification of the waste water - Google Patents

Description

35

The invention relates to a method for gassing a waste water / activated sludge mixture with oxygen and for denitrification of the wastewater in a circular or circular aeration basin of a long-term wastewater treatment plant, in which a ventilation area extends in the radial direction from the inner wall to the outer wall, with the treated wastewater is then fed to a receiving water via a secondary clarifier.

DE-OS 23 10 978 is already in the process of gassing a waste water / activated sludge mixture with oxygen Became known in a long-term wastewater treatment plant. There is attainment an economical oxygen input into the sewage-activated sludge mixture with a mechanical one Circulation of this mixture with the least possible expenditure of energy in the circular aeration basin the sewage / activated sludge mixture present is subjected to a three-dimensional flow, d. H. the circular flow created around the vertical axis of the container creates a cross flow, which runs along the horizontal pelvic floor and near the center of the pelvis through guide surfaces to one ascending flow is diverted. The oxygen input into the sewage-activated sludge mixture is supposed to be are kept at the lower limit by measuring and control devices, with the oxygen input should always be optimally adapted to the needs.

What measures are used to measure and regulate the oxygen input, DE-OS 23 10 978 gives no information about this.

In addition, it can happen that the amount of oxygen supplied • easily over in an uneconomical manner goes beyond the necessary extent so that no good denitrification of the wastewater can occur; consequently Significant amounts of nitrate can still get into the receiving water and cause silting there.

The invention is therefore based on the object in a method of the type mentioned To control oxygen input into the sewage-activated sludge mixture so that this oxygen input also with changing wastewater inflow is just sufficient to nitrify the wastewater and then to denitrify.

According to the invention, this object is achieved in that the oxygen content of the waste water-activated sludge mixture in the region of the downstream end of the ventilation zone is measured by a first probe and by means of control of the ventilation effecting air supply is kept as low as possible depending on the measurement result that in the Aeration zone subsequent oxygen-poor zone of the aeration basin the measurement of the oxygen content by the circulation speed of the sewage-activated sludge mixture and / or the conveying capacity the ventilation device controlling the second probe takes place, and that of the first probe outgoing control pulses from those of the second probe are superimposed.

The advantages achieved by the invention are essentially to be seen in the fact that only so much oxygen is entered in order to be able to nitrify the nitrogen compounds of the wastewater to be cleaned and further degradation and excretion of the nitrates using the oxygen To achieve nitrogen from wastewater. This means that the wastewater is largely and effectively cleaned achieved in the most economical way.

The cycle nitrification in the ventilated zone and denitrification in a subsequent oxygen-poor zone Zone is repeated with each cycle of the sewage-activated sludge mixture. This is a Accumulation of the nitrate content avoided and in many cleaning stages that are repeated one after the other achieved that the discharged purified wastewater still has a certain oxygen content, but only traces of Has ammonium and nitrate.

A suitable embodiment for the method according to the invention is the subject of the claim 2.

In the drawing, embodiments of the invention are shown for example, namely shows

F i g. 1 a circular aeration basin in plan view and

F i g. 2 one opposite F i g. 1 modified embodiment.

The wastewater / activated sludge mixture located in the circular aeration basin 1, the inlet of which is denoted by Z and the outlet of which is denoted by A , is aerated by an aeration device B fed by one or more air conveyors (not shown).

The wastewater / activated sludge mixture contained in the basin 1 is further set into a rotating movement illustrated by two arrows by a conveying device P. Both the conveyor P and the air conveyor are continuously adjustable, two preferably as

Oxygen measuring probes 51 and 51 designed as electric probes! to control the drive motors and the power of the conveyor P and the air conveyor, ie to control the speed of the sewage-activated sludge mixture and the amount of air per unit of time entered into the sewage-activated sludge mixture

In the embodiment according to FIG. 1, the ventilation device B consists of stationary aerators arranged on the bottom of the basin 1. Propellers or the like arranged separately therefrom as a conveying device P on a stationary bridge 2 are provided. Instead of propellers, a bridge that runs around the center point M of the basin 1 can also be provided as a conveying device, on which a dam or the like, not shown, immersed in the sewage-activated sludge mixture, extending transversely to the direction of rotation, is arranged

Furthermore, in the embodiment according to FIG. 1 the first measuring probe 51 is arranged at the end of the aeration zone or shortly after it, based on the direction of flow of the sewage-activated sludge mixture, and the second probe 511 is arranged in the subsequent low-oxygen area. The second probe 511 is located at a distance of at least about half the pool circumference from the aeration device B. Both probes 51 and 511 are fixedly arranged in the aeration basin 1 by being connected to the outer wall 4 of the basin.

In the embodiment according to FIG. 2, the aeration device Saus consists of a bridge 3 which is arranged in the direction of the arrow around the pool center M and is located at a small distance above the base of the pool Movement is displaced. The first probe 51, however, is not permanently connected to the outer wall of the basin 4, but is arranged on the circumferential bridge 3, specifically just behind the aerators of the ventilation device B in relation to the direction of rotation of the bridge. The probe 51 thus revolves with the bridge 3.

The second probe 511 is as in the embodiment of FIG. 1 fixed in basin B, based on the direction of flow of the sewage-activated sludge mixture upstream of the outlet A of the aeration basin 1.

The probes 51 and 511 are not shown appropriate switching and writing devices assigned. > o

In Fig. 1, the probe 51 (minimum probe) is provided behind the stationary aerators of the aeration device B , based on the direction of circulation of the sewage-activated sludge mixture, the probe 51 maintaining a predetermined lowest oxygen content, as found in the circulating sewage-activated sludge according to experience -Mixture adjusts behind the aerators in the sense of the circumferential movement. If the oxygen values deviate from the nominal value, the probe 51 causes changes in the aerator output.

The probe 51 controls a continuously variable drive motor of a compressor (not shown), which forms the air conveyor of the ventilation device B, for generating compressed air. If the oxygen content is too low or too high, the number of revolutions of the compressor is continuously reduced or increased.

The amount of air is set to a minimum, and in such a way that the oxygen content is sufficient for nitrification over a certain length of the circuit but then sharply decreased in the subsequent zone or drops to zero. In the deoxygenated zone will the oxygen demand of the microbes is covered by reducing the nitrates produced. With every turn Therefore, if the oxygen content is sufficient, nitrification and denitrification occur one after the other if there is little or no oxygen content.

The oxygen content in the area of the downstream end of the ventilation zone is kept as low as possible by means of the probe 51 (minimal probe); accordingly, the probe controls the output of the compressor as well as the circulation speed of the sewage-activated sludge mixture. It acts via a switching device on the steplessly adjustable compressor, which increases or decreases the air flow, so that the set minimum oxygen content is maintained unchanged during operation despite reducing or increasing the amount of waste water or the amount of dirt added with the waste water. The probe 51 can also act simultaneously or alone on the drive of the circulating wastewater / activated sludge mixture, ie on the drive of the propeller forming the conveying device P or the circulating bridge 3 with a dam.

In order to further control the fluctuations in the oxygen content as a result of the ingress of different amounts of water and contamination through inlet Z , the probe 511 is at any point as a control probe when carrying out the method with a fixed ventilation device B according to FIG. 1, preferably shortly before the outlet A provided. If an excessively high lack of oxygen occurs during a cycle of the sewage-activated sludge mixture, then by superimposing the control pulses emitted by probe 51 with those of probe II, the drive for the air conveyor of the aeration device B and the drive for generating the circulating speed of the sewage - Activated sludge mixture continuously increased.

This superimposition lasts until the required oxygen content drops to the value set by the probe 51 due to a lower inflow and / or a lower level of contamination of the waste water. Then the increased air supply to the ventilation device B and the increased circulation speed of the sewage / activated sludge mixture are reduced again by reducing the overlay.

Is the oxygen level displayed by probe 511 too high, then the amount of ventilation must be reduced and the bridge must be moved more slowly.

FIG. 2 illustrates the implementation of the method in FIG The embodiment of an aeration basin with all-round ventilation. The probe 51 is not here, however firmly connected to the pool wall, but it is behind the ventilation in the sense of the pool circulation provided and circulates with the bridge.

In the embodiment according to FIG. 2 controls the probe 51 as in the embodiment of FIG. 1 in the manner indicated above, the minimum ventilation and the minimum circulation speed according to a predetermined minimum oxygen value. The control pulses of the probe 511, which can be provided at any point, but if possible before the outlet A of the purified wastewater / activated sludge mixture, are superimposed again when the oxygen deficiency is too high

Pelvic section with that of the probe 51; this then causes an increase in the amount of air per unit of time Circulation speed of the sewage-activated sludge mixture by increasing the circulation speed the bridge 3 can be enlarged, since the bridge is continuously adjustable by a controlled by it Motor is driven

However, if the probe 511 measures too long a duration If the oxygen content is too high during a cycle, the compressor's delivery rate can be reduced and the bridge speed and thus the speed of circulation of the sewage-activated sludge mixture be reduced.

When carrying out the method according to FIG. 2, a dam T extending transversely to the circulating flow of the waste water / activated sludge mixture can also be provided within the aeration basin 1. The damming gate T has openings O for the passage of the air supply pipes (not shown) leading from the bridge 3 down to the ventilators of the ventilation device B and is preferably arranged in the circumferential direction just behind the outlet A so that the probe 511 is located in front of the damming gate T. . The openings O are adjustable in their clear width. In addition, the circumferential aerators provided above the base of the pool can be enlarged or increased or reduced or reduced.

1 sheet of drawings

Claims (2)

Patent claims: 1. Process for the oxygenation of a waste water / activated sludge mixture and for denitrification of the wastewater in a circular or circular aeration basin of a long-term wastewater treatment plant, in which a ventilation area extends in the radial direction from the inner wall to the outer wall, the cleaned Wastewater is then fed to a receiving water via a secondary clarifier, characterized in that that the oxygen content of the wastewater-activated sludge mixture in the range of downstream end of the ventilation zone is measured by a first probe and by means of Control of the air supply causing the ventilation as a function of the measurement result as far as possible is kept low that in the adjoining the ventilation zone, the low-oxygen zone des Aeration basin the measurement of the oxygen content by a the circulation speed of the Wastewater-activated sludge mixture and / or controlling the delivery rate of the aeration device second probe takes place, and that the control pulses emanating from the first probe from those of the second probe are superimposed. 2. The method according to claim 1, characterized in that that the first probe on a fixed, from her via a switching device and an air conveyor controlled and constant even with changes in the amount of dirt added with the wastewater maintained minimum oxygen content is set.