DE10059839A1 - Thickening of excess sludge in a wastewater treatment plant, employs deposited sludge as a filtration aid in a conical sieve, with a screw scraping inner surface - Google Patents

Abstract

The thickening unit comprises a conical sieve (10) into which the sludge is introduced. Most sludge particles deposit on the inner wall, rather than passing through. Filtrate flowing through the sieve walls to the exterior and is returned to the waste water treatment process. The deposit forms a filtration aid and its thickness is controlled by a scraping and conveying screw (12) with conicity matching that of the sieve walls. It is adjusted axially, relative to them. An Independent claim is included for the thickener, constructed with a slotted screen.

Description

The invention relates to a process for thickening sludge in mechanical-biological wastewater treatment plants, in which bio-logical sludge from the secondary clarifier is returned to the upstream activation tank while the excess sludge is removed from the treatment process, and to the device for carrying out the process. In today's mechanical-biological wastewater treatment plants, there are considerable amounts of thin sludge, the water content of which is 97% and above. In the case of sludge from biological purification or chemical phosphorus precipitation, the water content is even more than 99%. After removing such sludge from the wastewater treatment process, it is used for various purposes or other treatment processes. Common are:

• - Temporary storage in large thickening containers and subsequent wet application on agricultural land.
• - Transport to another sewage treatment plant for further treatment or drainage
• - mechanical drainage
• - Anaerobic sludge stabilization (digestion).

The high water content of the thin sludge and the associated high To reduce investment and operating costs, the thin sludge is on concentrated. This is done either by static thickening with continuous ierlicher or discontinuous water drainage or via belt or Drum filter.

In DE-PS 34 26 742 C2, for example, a mud water drain is in one Thickening container described, which is only under static pressure works, and in which the dirty wastewater from the outside through the sieve wall of a screen cylinder as a filtrate in the interior of the screen cylinder flows. Thickening via centrifuges with or without flocculation aids medium is known.  

In addition to the bad smell because of the long dwell time in such large Thickening containers with only a small thickening effect are the high ones Investment costs, due to the large storage containers, the mechanical ones Facilities and their housing, disadvantageous. High operating costs also arise cost through chemicals and the energy required. With all known The procedure is the back-loading of the sewage treatment plant by the separated restver dirty water an undesirable side effect. Depending on the process and pretreatment also occurs due to the long residence times of the biologically bound phosphates, which in addition to a burden the wastewater treatment plant.

The invention has for its object an effective thickening of thin sludge without flocculants with little back pressure to the sewage treatment plant to achieve low investment and operating costs.

To solve this problem, the features specified in the claim proposed. Further inventive measures and devices are in specified in the subclaims.

The excess thin sludge is directly from the cleaning process conveyed into the inside of a screen cylinder and through the screen cylinder wall pushed outwards. The solids are retained, and that the filtrate penetrating the sieve wall is returned directly to the process recycled.

The drawing shows the method and the method suitable for carrying it out Device shown on embodiments. Show it:

Fig. 1 is a diagram of the process flow of the biological cleaning process

Fig. 2 A screen cylinder in a vertical arrangement

Fig. 3 The filter aid layer building up in the screen cylinder on a larger scale

Fig. 4 is a schematic representation of the control of the desired thickness of the filter auxiliary layer

The wastewater freed from coarse impurities is fed to the activation tank 1 via the inlet 2 . In the aeration tank 1 , aeration elements 3 for the supply of finely distributed air bubbles and a water circulation device 4 are accommodated. In the aeration tank 1 , the pollutants present in the wastewater are broken down by means of microbes. Subsequently, the biologically treated wastewater in the aeration tank 1 with predominantly still living microbes is transferred to the secondary clarifier 5 . The settling sludge settling on the bottom of the secondary clarification tank 5 , which is formed from microbes, reaches the return sludge pumping station 6 as thin sludge via the static pressure. By means of the return sludge pump 7 , the return sludge necessary in the activation tank 1 for the continuation of the process with its still active microbes is returned to the activation tank 1 , while the excess sludge is fed with the thin sludge pump 8 to the thickening device 9 .

The sewage sludge accumulating in the secondary clarifier has a very high water level stop, namely usually over 97% (thin sludge) and must be from this water be separated as much as possible to avoid high follow-up costs for transport and Avoid elimination. This is where the invention comes in.

According to FIG. 2, the thickening device 9 consists of the conical Siebzylin 10 with the thin sludge connection 11 , the scraping and conveying screw 12 arranged in the sieve cylinder 10 , the outer jacket 13 and the thick sludge pressure line 14 with the throttle device 15 . With the vertical arrangement of the thickening device according to FIG. 2, the entire unit can be suspended from an upper bearing unit 16 , and thus a lower bearing with its clogging and sealing problems is eliminated. Via the pressure line 17 of the thin sludge pump 8 , the thin sludge is pumped through the thin sludge connection 11 into the interior of the screen cylinder 10 . While a large part of the water content is pressed by means of the pump pressure through the sieve wall of the sieve cylinder 10 into the outer annular chamber 18 formed by the jacket 13 , sewage sludge settles on the inside of the sieve cylinder 10 and forms a coating which acts as an additional filter auxiliary layer. The scraping and conveying screw 12 is axially displaceable in the sieve cylinder 10 , so that the outer scraping edges 19 approach more or less uniformly over the entire length of the inner wall of the sieving cylinder 10 during the displacement, because the conicity of the sieve cylinder 10 and the scraping line of the scraping and conveying screw 12 are coordinated. In this way, the thickness of the filter auxiliary layer can be controlled, or the entire covering can be scraped off. The pressure building up in the screen cylinder 10 can be controlled via the pump pressure of the thin sludge pump 8 , the setting of the throttle device 15 at the thick sludge discharge and the thickness of the filter auxiliary layer building up. In this way it is possible to determine the achievable degree of drainage within certain limits without any problems. In addition, the natural wear of the thickening device 9 is limited to a minimum by the distance between the inner wall of the screen cylinder 10 and the scraping line of the scraping and conveying screw 12 . Because in the case of cylindrical sieves with a constant diameter, the scraping edges inevitably wear out, the conveyor screw must be replaced after a certain time. In the conical design of the screen cylinder and screw conveyor, wear compensation by adjusting is possible. The speed of the scraping and conveying screw 12 is also expediently controllable in order to be able to optimally coordinate the operating state with one another.

The screen cylinder 10 is preferably designed as a slotted screen, since the wedge-shaped gaps are not sensitive to clogging. Fig. 3 shows a section through the screen cylinder wall on a larger scale. The wire 20 forming the slotted wire has a triangular cross-section, with a broad side 21 pointing towards the inside of the screen cylinder, and which form narrow gaps SP with a small distance next to one another, which continuously widen outwards. This significantly reduces the risk of constipation. Because of the pressure prevailing in the screen cylinder, which is considerably higher than the static pressure, no disturbing deposits of adhesive components can form behind the outlet gaps SP.

A filter auxiliary layer 22 is deposited on the inside of the screen cylinder 10 , the thickness of which is determined by the position of the scraping and conveying screw 12 and which also retains smaller particles. FIG. 4 shows this schematically at two different positions, the scraping and conveying screw being moved deeper into the screen cylinder 10 in position a than in position b, and thus a thinner filter auxiliary layer is formed. Of course, sieve cylinders with round or elongated sieve openings (perforated plate) can also be used.

While the thickened sludge is conveyed through the thick sludge pressure line 14 into a container 23 when the scraping and conveying screw 12 is rotated, the largely cleaned filtrate is fed back via the filtrate outlet 24 back into the activation tank 1 .

In the pressure line 17 of the thin sludge pump 8 , an adjustable pressure relief valve 25 is installed in order to ensure the safety of the system when the pressure builds up too high. The possibility of axial adjustment of the scraping and conveying screw 12 can be seen in FIG. 2. The drive shaft 27 of the scraping and conveying screw 12 , which can be driven via the motor 26, is mounted in a fixed housing 28 by means of a sliding bush 28 a, which can be moved axially by the stroke H via the pinion 30 of the adjusting motor 31 and the toothing 29 . All control signals can be directed from a control cabinet 32 to which the individual control elements.

When thickening biological excess sludge according to the present Invention, the back load of the sewage treatment plant is extremely low, namely practically zero, since the thin sludge is made directly without intermediate storage is taken from the process. For the solids still contained in the filtrate is active biomass from microbes, which is directly in the Cleaning process is included. In conventional processes with template the biomass, on the other hand, has at least partially died, so that the returned solids mostly from dead small creatures exist, which pollute the sewage treatment plant again as dirt freight. Moreover becomes biologically bound phosphate due to the longer storage partially resolved, which is now no longer applicable. On top of that, through the filtering under the pressure that builds up the throughput Lich is increased, and the resulting thick sludge drains very high degree of efficiency. Thanks to the variable setting options for operation pressure, the thickening process can be controlled so that it is discharged as sludge a puncture-proof mass is created.

Claims (14)

1. Process for sludge thickening in mechanical-biological wastewater treatment plants, in which biologically active sludge is returned from the secondary settling tank to the upstream activation tank and excess sludge is fed to a thickening device, characterized in that

• a) the thickening device ( 9 ) consists of a conically tapering sieve cylinder ( 10 ), into the interior of which the return sludge is introduced, the sludge particles mostly being deposited on the inner wall of the sieve cylinder, while the filtrate penetrating the outside of the sieve cylinder back into the wastewater treatment process is returned, and
• b) the thickness of the deposit made of sewage sludge which settles on the inner wall of the conical sieve cylinder ( 10 ) and serves as a filter auxiliary layer ( 22 ) by means of a scraping and conveying screw (which is axially displaceable inside the sieve cylinder ( 10 ) and is longitudinally displaceable relative to the sieve cylinder ( 10 ) 12 ) is regulated with a conical outer scraping line.

2. The method according to claim 1, characterized in that the excess return sludge from the secondary settling tank ( 5 ) of the thickening device ( 9 ) is fed under pump pressure, the pump pressure supporting the filtrate separation. 3. The method according to claim 1 or 2, characterized in that the degree of dewatering of the excess sludge is controlled via the pump pressure of the thin sludge pump ( 8 ) and a throttle device ( 15 ) attached behind the conical sieve cylinder ( 10 ). 4. The method according to any one of claims 1 to 3, characterized in that the degree of separation is controlled via the thickness of the filter aid layer ( 22 ) forming on the inner wall of the conical screen cylinder ( 10 ). 5. The method according to any one of claims 1 to 4, characterized in that the forming on the inner wall of the screen cylinder (10) filter-aid layer (22), screw means of the displaceable and rotatable scraping and conveyor (12) at least partially peeled is and the peeled sludge is discharged from the screen cylinder ( 10 ) into the thick sludge pressure line ( 14 ). 6. The method according to any one of claims 1 to 5, characterized in that the filter auxiliary layer ( 22 ) is partially peeled off at intervals. 7. The method according to any one of claims 1 to 5, characterized in that the filter auxiliary layer ( 22 ) forming on the inner wall of the screen cylinder ( 10 ) is completely peeled off at intervals. 8. The method according to any one of claims 1 to 5, characterized in that the filter auxiliary layer ( 22 ) forming on the inner wall of the screen cylinder ( 10 ) is continuously peeled off. 9. Device for performing the method according to one of claims 1 to 8, characterized in that the conical screen cylinder ( 10 ) is designed as a slotted screen. 10. The device according to claim 9, characterized in that the slotted screen consists of a spiral wound to a conical sleeve wire ( 20 ) with a triangular cross-section, wherein a base ( 21 ) is directed towards the screen cylinder interior. 11. Device according to one of claims 9 or 10, characterized in that an axially longitudinally displaceable and rotatable scraping and conveying screw (12) is arranged in the screen cylinder (10) which is formed by the saddle fire outer contour in the same conicity as the screen cylinder (10) is trained. 12. Device according to one of claims 9 to 11, characterized in that the thickening device ( 9 ) with screen cylinder ( 10 ) and the scraping and conveyor screw ( 12 ) is arranged vertically. 13. The apparatus according to claim 12, characterized in that the thickening device ( 9 ) with screen cylinder ( 10 ) and the scraping and conveyor screw ( 12 ) is attached to an upper bearing unit ( 16 ) hanging. 14. Device according to one of claims 9 to 13, characterized in that the drive shaft ( 27 ) of the scraping and conveying screw ( 12 ) in a fixed housing ( 28 ) with a movable hub (H) sliding bushing with teeth ( 29 ) on a pinion ( 30 ) can be moved axially by means of an adjustment motor ( 30 ).