DE3815865A1 - Apparatus for support-immobilised waste water purification - Google Patents

Abstract

The invention relates to an apparatus for the biological purification of waste water (effluent) in a reactor 3, in which are arranged support material elements 4 made of open-pored plastic foam as a growth surface for biomass. According to the invention, it is proposed to design the support material elements 4 in such a way that they have a baseplate 1 from which project longitudinal bodies 2. <IMAGE>

Description

The invention relates to a device for biological Wastewater treatment with a reactor in which at least one Carrier material element made of open-cell foam as Growing area for biomass is arranged, and an inflow for wastewater to be cleaned and a drain for cleaned Sewage.

Win plants for carrier-bound wastewater treatment increasingly important. By settling the biomass on Carrier materials can be compared to activated sludge plants higher biomass concentration in the reactor and thus a higher Cleaning performance can be achieved. For example, are known Plants in which open-pore foam particles in the reactor float freely in the waste water. For example, on the EP-PS 75 298 referenced. To ensure a good exchange of materials between the wastewater ingredients in and on the Foam particles settled biomass and possibly To ensure oxygen dissolved in the wastewater, the Foam particles have relatively small dimensions. Common are e.g. Foam cubes with 1 to 1.5 cm edge length. Around flushing out these foam particles with the To prevent cleaned wastewater must be in the reactor close-meshed drain strainer. Usually  the drain strainer has holes with diameters of approx. 0.7 to 1 cm. Such screens are expensive on the one hand Acquisition, on the other hand, they can be carried out in the sewage existing coarse materials are blocked. Also one can Drainage of foam from the reactor can be inhibited. A total of Such systems can cause faults and Breakdowns come.

On the other hand, it is also known as foam boards Settlement area for biomass fixed in one reactor to arrange (DE-PS 33 27 774). This will make the attachment a fine-meshed drain filter and a return of Support material elements from the outlet to the inlet of the reactor superfluous, so that there are no clogging problems at the outlet arise. However, such systems have the disadvantage that relatively small amounts of biomass with a small plate thickness can be fixed or with a larger panel thickness Mass transfer between those located in the foam Biomass and the wastewater ingredients are not is satisfactory. So all in all, too Plants no satisfactory cleaning performance.

Therefore, the task still had to be solved for economic and effective processes for improved Waste water treatment suitable carrier material elements for To make available.

The present invention is therefore based on the object to design a device of the type mentioned in the introduction, that an effective, economical and reliable system is provided for improved wastewater treatment.

This object is achieved in that the Carrier material element has a base plate from which protrude elongated body.  

The carrier material element thus obtained becomes as follows manufactured: A foam block is made from one side incised or punched out that elongated bodies, e.g. Cuboids, prisms or cylinders, arise over a Stay connected to the base plate. Alternatively, a Foam block or a foam sheet corresponding Thickness can be cut over profile rollers so that Finger-like, almost conical profiles are created.

The carrier material element created in this way offers on the one hand, the biomass has a large settlement area, on the other hand due to its loosened spatial Structure also an intensive mass exchange between the in and bacteria sitting on the foam and the Waste water ingredients guaranteed.

The base plate of the carrier material element preferably has a thickness of approximately 3 cm and a base area of approximately 20 × 20 cm. Such carrier material elements are advantageously introduced into the reactor in such a way that they float freely in the waste water. If, on the other hand, the carrier material elements are to be permanently installed in the reactor, the base plate expediently has a thickness of approximately 3 cm to approximately 15 cm and a base area of approximately 200 cm × 200 cm. The bodies created by punching or cutting into the foam block have a base area of approximately 1-10 cm ² and a height of approximately 50 cm. With these dimensions of the carrier material element, in conjunction with the open-pore structure of the foam used, an optimal mass transfer is achieved with the greatest possible biomass concentration. The elongated bodies are substantially perpendicular to the base plate.

In a preferred embodiment of the invention, the Base plate of the carrier material element with a Reinforcement mesh made of metal or plastic. This will improve the mechanical stability of the Carrier element increased.

In a further development of the inventive concept, it is provided that Bend floor plates by 180 ° and the opposite ones To connect base areas with each other. In this way creates a more symmetrical base material element that are particularly suitable for use in fluidized bed reactors is suitable.

By bending the bottom plate into a pipe or pipe-like Form and fix the end edges of the so bent Bottom plate creates other shapes with similarity too Brush rollers.

The carrier material element or the carrier material elements can be permanently installed in the reactor. This has the advantage that there is no drift of the carrier material elements to the process, so that no return conveyors are necessary. The carrier material elements are thus preferably in the reactor installed that the bottom plates of the carrier material elements perpendicular to the flow direction of the waste water in the reactor are directed, i.e. are the surface normals of the floor slabs directed parallel to the flow direction of the waste water. In particular in the formation of the carrier material elements as Pipe or pipe-like structure is affected by a flow of the tubular support material element additionally positive the cleaning performance. The inside of the pipe works quasi as a separate reactor, the open-pore wall of the Pipe is occupied with biomass.  

Another option is to use the Introduce carrier material elements into the reactor so that they float freely in the waste water. Because of the relatively large Dimensions of the carrier material elements is sufficient for one Restraint of the carrier material elements from the reactor outlet coarse mesh sieve. The sieve preferably has one Mesh size of more than approx. 10 cm. This allows in Coarse materials present in wastewater that are smaller than that Carrier material elements, pass through the sieve and do not lead to Blockages in the reactor outlet. Also are coarse screens inexpensive to purchase, so that larger reactors, e.g. B. Longitudinal aeration tank, in several sections by attachment can be divided by coarse sieves. This eliminates the need a return of the carrier material elements from the process to feed the reactor.

In further development of the inventive concept is also provided in the body of the carrier material element to install closed-cell foam. This will help free-floating arrangement of the carrier material element in the Waste water increases the buoyancy of the carrier material element.

The carrier material elements can also be used as immersion trickling filters used, for example, on a roller mounted, which is partially immersed in the wastewater. By The individual carrier material elements become rotating the roller periodically submerged in and out of wastewater lifted out.

The device according to the invention is suitable both for aerobic as well as for anaerobic biological wastewater treatment.  

In the first case, it is possible, for example, as the reactor Training aeration tanks, the aeration candles for has the supply of the necessary ventilation gas. At Use of the device according to the invention for anaerobic For example, wastewater treatment is also possible Carrier elements in a closed reactor in the form to arrange a fixed bed from the top of the wastewater is flowed through below. Also used for nitrification or denitrification of wastewater is planned.

In the following the invention is based on in the figures schematically illustrated embodiments explained.

Show it:

Fig. 1 shows a single carrier material element with a flat base plate.

Fig. 2 shows a single carrier material element with a bottom plate bent into a tube.

Fig. 3 shows an aeration tank with tubular support material elements that float freely in the waste water.

The carrier material element shown in FIG. 1 was made from an open-celled macroporous foam block, in which the foam block was cut from one side in such a way that elongated cuboid bodies 2 with a base area of approx. 1 × 1 cm and a height of approx. 25 cm were created, which remained connected to each other via a base plate 1 . For the sake of clarity, only four bodies are shown in FIG. 1. In practice, however, carrier material elements with a large number of such bodies will be used. The base plate 1 has a thickness of approximately 3 cm and a base area of approximately 20 × 20 cm. A large number of these carrier material elements are firmly installed in an aeration tank in such a way that the surface normal of the base plate 1 is directed parallel to the flow direction of the waste water. In this way, on the one hand, the flow of the wastewater is not obstructed too much, on the other hand, an intensive exchange of substances between the microorganisms that are located in and on the foam is guaranteed.

Fig. 2 shows a carrier material element according to a further development of the inventive concept. The bottom plate 1 was bent into a tube and fixed at the end edges. The elongated bodies 2 project radially outward from this tube 1 . In practice, this carrier material element also has a large number of elongated bodies 2 . Only a few elongated cuboids 2 are shown in the present exemplary embodiment. Such carrier material elements are introduced into the reactor in such a way that they float freely in the waste water. In order not to excessively hinder the floating movement of the individual carrier material elements, it is expedient to introduce the carrier material elements into the reactor in an amount which corresponds to a volume fraction of 5 to 70% of the reactor volume. Depending on the filling density and the nature of the carrier material elements, a certain type of reactor can be generated depending on the pollution of the wastewater to be treated. Thus, the reactor is expediently operated as a fully mixed activation tank with a volume fraction of the carrier material elements of 5 to 40% and as a floating bed and / or fixed bed reactor with a volume fraction of the carrier material elements of 40 to 70%.

In Fig. 3, an aeration tank 3 is shown, in the carrier material elements 4 have been introduced so that they float freely in the waste water. The activation tank 3 has an inlet 6 and an outlet 7 for the waste water. The tubular elements shown in FIG. 2 are used as carrier material elements 4 . The carrier material elements 4 take up approximately 30% of the volume of the activation tank 3 . The activation tank 3 is operated as a fully mixed reactor. Due to the relatively large dimensions of the carrier material elements 4 (tube length approx. 20 cm, length of the bodies projecting from the tube approx. 50 cm), a wide-meshed sieve 5 can be used to hold back the carrier material elements 4 from the outlet 7 . In the present exemplary embodiment, the sieve 5 has a mesh size of approximately 15 cm. As a result, coarse materials present in the wastewater can pass through the sieve 5 unhindered, so that there can be no blockages or blockages in the outlet 7 , which would ultimately lead to malfunctions. Foam formed in the aeration tank can also flow freely through the sieve 5 .

Claims (13)

1. Device for biological wastewater treatment with a reactor in which at least one carrier material element made of open-cell foam is arranged as a growth surface for biomass, and an inlet for wastewater to be cleaned and an outlet for cleaned wastewater, characterized in that the carrier material element ( 4 ) has a base plate ( 1 ), from which elongate body ( 2 ) protrude. 2. Device according to claim 1, characterized in that the elongated body ( 2 ) are designed as cuboids, prisms, cones or cylinders. 3. Apparatus according to claim 1 or 2, characterized in that the body ( 2 ) have a base area of approximately 1-10 cm ² and a height of approximately 5-50 cm. 4. Device according to one of claims 1 to 3, characterized in that the base plate ( 1 ) is provided with a reinforcing fabric made of metal or plastic. 5. Device according to one of claims 1 to 4, characterized in that the base plate ( 1 ) is bent into a tube and connected at its end edges. 6. Device according to one of claims 1 to 4, characterized in that the base plate ( 1 ) is bent by 180 ° and is connected to its opposite base surfaces. 7. Device according to one of claims 1 to 6, characterized in that the carrier material element ( 4 ) is permanently installed in the reactor ( 3 ). 8. The device according to claim 7, characterized in that the base plate ( 1 ) has a thickness of about 3 cm to about 15 cm and a base area of about 200 cm × 200 cm. 9. Apparatus according to claim 7 or 8, characterized in that the carrier material element ( 4 ) is arranged in the reactor ( 3 ) so that the surface normal of the base plate ( 1 ) is directed parallel to the flow direction of the waste water. 10. Device according to one of claims 1 to 6, characterized in that the carrier material element ( 4 ) is arranged in the wastewater freely floating in the reactor ( 3 ). 11. The device according to claim 10, characterized in that the base plate ( 1 ) has a thickness of about 3 cm and a base of about 20 cm × 20 cm. 12. The apparatus of claim 10 or 11, characterized in that before the outlet ( 7 ) of the reactor ( 3 ), a sieve ( 5 ) with a mesh size of more than about 10 cm is attached. 13. Device according to one of claims 10 to 12, characterized in that in the body ( 2 ) of the carrier material element ( 4 ) closed-cell foam is installed.