WO1995018071A1

WO1995018071A1 - Waste water treatment plant with immersed bodies

Info

Publication number: WO1995018071A1
Application number: PCT/EP1994/004293
Authority: WO
Inventors: Hans-Hugo Adelhütte
Original assignee: OMS KLÄRANLAGEN GmbH
Priority date: 1993-12-24
Filing date: 1994-12-23
Publication date: 1995-07-06
Also published as: DE4344498A1; HU9601862D0

Abstract

A waste water clarification plant with immersed bodies has a clarification basin in which is arranged a roller-shaped immersed body. The plant is characterised in that the immersed body consists of a main roller-shaped body (2) completely submerged under the water level (6) in the clarification basin (1) and of at least one secondary body (3) that rotates around the main body in a substantially vertical plane, extending at least partially above the water level in the clarification basin.

Description

Immersion body management

The invention relates to a submersible system for the purification of waste water.

Activated sludge systems or fixed bed systems have long been known for the purification of waste water, in which the organic constituents of the waste water to be treated are breathed in various proportions with the aid of living microorganisms or converted into removable biomass. More recently, activated sludge developments with regard to fixed bed or immersion systems have been sought, since these systems have the advantages that less sludge is produced, a return sludge is rarely required, the energy consumption is lower and the operational reliability is high. In these immersion bodies, the immersion body is covered with a biological turf, so that the immersion body is the point of contact of the microorganisms with the waste water. In addition to the submerged, artificially ventilated immersion bodies, there are, for example, roller-shaped rotating immersion bodies which are arranged in a treatment tank. For example, they consist of individual disks. The roller-shaped immersion body rotates slowly around its longitudinal axis. Since it partially projects above the water level in the treatment basin, it continuously absorbs the oxygen required for the metabolism of the microorganisms during the rotation. The wastewater is only cleaned up to nitrification. Denitrification is not possible in these immersion body systems, so that an additional one Denitrification level is required. Such denitrification and, at the same time, biological phosphorus elimination is generally sought today in wastewater treatment plants.

The object on which the invention is based was now to obtain an immersion body system, by means of which not only nitrification but also denitrification and biological phosphorus elimination can be carried out in an apparatus-based cleaning stage.

The immersion body system according to the invention for the purification of waste water with a treatment basin and a roller-shaped immersion body arranged therein is characterized in that the immersion body consists of a roller-shaped main body which is arranged completely below the water level in the treatment basin and at least one which rotates in a substantially vertical plane around the main body and thereby there is at least partially secondary body reaching over the water level in the treatment basin.

The usual anoxic or anaerobic cleaning processes, such as denitrification and phosphorus elimination, can take place on the roller-shaped main body, which is completely immersed in operation, without supplying oxygen through the secondary body. On the other hand, oxygen can be conveyed into the treatment basin and the main body with the aid of the secondary bodies which at least partially protrude above the water level, which enables the aerobic cleaning processes, such as carbon degradation and nitrification.

The secondary bodies of the submersible body system according to the invention are preferably likewise cylindrical and extend over the entire length of the cylindrical main body or a part thereof. The cylindrical main and secondary bodies can have a round or polygonal cross section.

The main and / or secondary bodies expediently consist of individual disks which are constructed like corrugated cardboard to enlarge the surface and have cavities in which the microorganisms can settle. The system according to the invention expediently has at least four secondary bodies running around it per cylindrical main body.

The surface of the secondary body can be arranged so that it runs around that of the main body at a distance. However, the surfaces of the main body and the secondary body are preferably lamella-like, at least in the outer region, these being comb-like External areas of the main and secondary bodies interlock with one another, which promotes the introduction of oxygen into the main body.

The roller-shaped main body can rotate slowly in the wastewater to be cleaned, but it is preferable to have it fixed so that only the secondary bodies move around it. During this orbital movement around the main body, the secondary bodies can optionally also rotate about their own longitudinal axis.

According to a particularly preferred embodiment, the secondary bodies are structured in such a way that they have a shovel-like function. If, as is expedient, they are constructed from individual disks, the channels in the interior of the disks are designed such that the channel walls have a shovel-like function on one side. In connection with secondary bodies designed in this way, it is expedient if the circulation of the secondary bodies around the main bodies is reversible, i. H. the secondary bodies can revolve around the main body in the two possible directions. The shovel-like walls of the channels in the secondary bodies are then designed such that they work like shovels only in one of the circumferential directions, but not in the other circumferential direction.

When such a system is in operation, it conveys the secondary bodies around the main body in a direction of circulation by means of the scoop-like structure to oxygen in the treatment basin and the main body, with the result that carbon is broken down in this phase of the process and nitrification he follows. If, after a certain time, the secondary bodies are switched in the opposite direction of rotation, no more oxygen is conveyed from them into the main body and the treatment basin, so that in this phase of the process only the contents of the basin are homogenized with the feed substrate and anoxic in the main body or anaerobic processes, in particular denitrification and biological phosphorus elimination, can take place. The two phases of the circulation of the secondary bodies can be preprogrammed with their direction of rotation and speed.

In a further preferred embodiment of the invention, the treatment basin has a cover with opening flaps, which preferably open automatically or can be opened by an automatic control system. These opening flaps are or are closed in a denitrification phase so that no further atmospheric oxygen can penetrate into the interior of the reactor. It is also expedient if, preferably for the operation during such a denitrification phase, the secondary bodies can be fixed so that they do not enter any further atmospheric oxygen into the treatment basin, while at the same time the completely immersed main body can continue to rotate and the pelvic contents are thereby circulated despite the standing secondary body. These features mentioned above are not expressly shown in the figures, but can nevertheless be provided in connection with the embodiments shown there.

The systems according to the invention have significant advantages over known immersion body systems. In an apparatus stage, carbon degradation and nitrification on the one hand and denitrification and biological phosphate elimination on the other hand can be carried out. You get a proportionally larger fixed bed area in the same space, an optimal transport of oxygen and substrate in the system, you save energy costs because the main body can be fixed, there is no risk of sludge build-up in the immersion body system and no sludge deposition in the installation system, you get constructional and transport advantages .

Mean in the drawing

1 is a vertical section through an embodiment of an immersion body system according to the invention,

Fig. 2 is a plan view of a submersible system according to the invention with the central part cut away, one embodiment being shown in the upper half and another embodiment being shown in the lower half, and

Fig. 3 is a vertical section through a secondary body with a shovel-like function according to a preferred embodiment of the invention.

1 has a treatment tank 1 with a water level 6, which is maintained by a conventional device, such as an overflow weir (not shown). In the treatment basin 1, completely submerged under the water level 6, there is a cylindrical main body 2, which is expediently constructed from individual disks with channels therein and, according to a preferred embodiment of the invention, is fixed, ie not rotatable, mounted. Around the longitudinal axis 4 of the main body 2, a carrier cross 7 rotates with secondary bodies 3 fastened to the ends, which can, if necessary, rotate again about their longitudinal axes 5. The main body 2 and the secondary bodies 3 are designed in the manner of lamellae or combs such that they mesh with one another in a tooth-like manner so that the cross sections of the secondary bodies 3 overlap the cross section of the main body 2. The direction of rotation of the secondary body 3 around the main body 2 is preferably reversible, so that the direction of rotation in the drawing can be to the left or to the right. In any case, the device for adjusting the water level 6 is designed such that the auxiliary bodies 3 partially emerge from the water as they circulate around the main body 2 at the upper end of the treatment basin 1.

As mentioned, two alternative embodiments of the invention are shown in the top view of FIG. 2. Identical parts in FIG. 2 have the same reference numerals as in FIG. 1, for the embodiment shown in the upper part each with an apostrophe. The embodiment shown in the lower part of FIG. 2 corresponds to that of FIG. 1.

In the upper half of FIG. 2, a roller-shaped main body 2 'constructed from disks and likewise constructed auxiliary bodies 3' are arranged in the treatment basin 1 '. The main body 2 'is not rotatably fastened in the treatment basin 1'. A support cross 7 'is arranged around its longitudinal axis 4', the ends of which support the longitudinal axes 5 'of the secondary body 3'. The main body 2 'and the secondary body 3' are spaced from each other so that they do not interfere with each other.

The embodiment shown in the lower part of FIG. 2 corresponds to that of FIG. 1 and differs from the embodiment shown in the upper part of FIG. 2 in that the secondary bodies 3 are interlocked with the main body 4 and interlock. This latter embodiment is preferred because it better introduces the oxygen into the main body 2 through the secondary bodies 3.

FIG. 3 shows how, according to a preferred embodiment of the invention, the channels in the secondary bodies can be designed in the manner of a scoop. 3 shows a vertical section through a secondary body or a disk of a secondary body, wherein 9 channels 8 are formed by partitions. These channels have such an angular position in the upper and lower part of the drawing that they act like a blade in the direction of rotation indicated by the arrow A, but not when rotating in the direction of the arrow denoted by B. In the direction of rotation A, oxygen is conveyed into the treatment basin and the main body, but not in the direction of rotation B.

Claims

Patent claims

1 . Immersion body system for the purification of waste water with a treatment basin and a roller-shaped immersion body arranged therein, characterized in that the immersion body consists of a roller-shaped main body (2, 2 ') arranged completely below the water level (6) in the treatment basin (1, 1'). and at least one secondary body (3, 3 ') which runs around the main body in a substantially vertical plane and at least partially reaches above the water level in the treatment basin.

2. immersion body system according to claim 1, characterized in that the main body (2) and the secondary body (3) are comb-like and are interlocked at least in the outer area.

3. immersion body system according to claim 1 or 2, characterized in that it has at least four secondary bodies (3, 3 ').

4. immersion body system according to one of claims 1 to 3, characterized in that the main body (2, 2 ') is non-rotatably fastened in the treatment tank (1, 1').

5. immersion body system according to one of claims 1 to 4, characterized in that the secondary bodies (3, 3 ') are additionally rotatably mounted about their own longitudinal axis (5, 5').

6. immersion body system according to one of claims 1 to 5, characterized in that the direction of the circulation of the secondary body (3, 3 ') around the main body (2, 2') is reversible.

7. immersion body system according to one of claims 1 to 6, characterized in that the main and / or secondary bodies (2, 2 '; 3, 3') are constructed from individual disks.

8. immersion body system according to one of claims 1 to 7, characterized in that the secondary body (3, 3 ') have in their interior an outwardly open channel system (8).

9. immersion body system according to claim 8, characterized in that the Kanalwandun¬ gene (9) in the vertical section through the secondary body (3, 3 ') are at least partially angled with respect to the radius.

10. immersion body system according to one of claims 1 to 9, characterized in that the treatment basin has a cover with opening kiappen.

1 1. Immersion body system according to claim 10, characterized in that the opening of the cover can be closed automatically depending on the treatment phase.

12. immersion body system according to claim 10 or 1 1, characterized in that preferably with closed opening kippen the secondary body are essentially fixed in place, while the main body remains rotatable.