DE4008676A1 - Appts. for aerobic treatment of waste water - using oxidising agent and shearing machine rotor-stator - Google Patents

Abstract

Appts. treats waste water using oxidising agent and rotor-stator shearing machine. Oxidising agent is mixed with waste water. Mixt. is sheared in rotor-stator machine which breaks it up into fine particles. This results in higher rate of O2 transfer. Waste water is taken from a basin via pipe to the shearing machine. A pump injects liq. oxidising agent via another pipe and blower feeds air into machine via its connecting pipe. Fine particles which are produced are fed via a pipe to distributor. ADVANTAGE - Appts. uses hydrogen peroxide or potassium permanganate. It makes economic use of oxidising agent and is more effective.

Description

The invention relates to a method for aerobic Wastewater treatment by adding Oxidizing agents and mixing the same with the treating water, as well as a device its implementation.

This is the case with aerobic wastewater treatment general problem, an oxygen supplier Oxidizing agent in the water to be treated solve and the oxygen to the oxidized Bring substances. The actual Oxidation process runs as an exotic reaction spontaneously. Usually such a Wastewater treatment in oxidation tanks or Oxidation ponds carried out, that is, in shallow Containers with a low water column. That too Treating water is in these pools or ponds initiated, and as an oxidizing agent in all Usually air is supplied via a distribution system. The task of this distribution system is to keep the air in Enter the shape of the smallest possible bubbles, because the solution and thus the exploitation of the entered oxygen significantly from the size the bubbles hang down. The one with the known ones Distribution systems achievable bubble size is for a high oxygen input is still too large all because the dwell time because of the low water column for an effective Oxygen exchange is not sufficient.  

For this reason, an attempt has been made to oxygenate with the help of in the reaction basin mounted agitators, propellers and To increase ejector aerators. Examples of this are the "Fuchs environmental aerator" from F. G. W Fuchs Gas and water technology and the "Submersible Aerator" PODB-I from Landia. Those with these facilities achievable improvement in oxygen input is however very limited.

It was therefore with fermenters, i.e. H. closed Containers with agitators - sometimes very high - tries to improve the oxygen input or to optimize (see Chemistry 8. Volume "1979" No. 7, pp. 330/331 and Chemical engineering 51 "1979" No. 4, pp. 288-294). However, this was only partially successful, because here too too much of the entered oxygen remains unused.

When using liquid or in liquids dissolved oxidizing agents instead of air the difficulty of this in the mostly very high Distribute reaction vessels evenly enough, since these are very small amounts in proportion deals with the amount of water to be treated.

It is particularly problematic to bring the Oxidizing agent, d. H. of oxygen to the oxidizing substances in highly viscous or slimy substances.

The invention is based, the Oxygenation during aerobic wastewater treatment significantly improve and thus the To make wastewater treatment more economical and both in terms of operating costs as well the investment costs.  

We do this in a procedure of the beginning described type solved in that treating water and oxidizing agent in the Shear field of a rotor-stator machine like her described for example in EP OS 87 10 85 684 is supplied, in which the components in smallest units of measure divided and under the Exposure to high shear forces and high frequency Alternating stresses are mixed intensively and that during treatment in this shear field high power input into the mixture. At Such a process is due to the extremely high Shear frequency to which this mixture is exposed, both a practically homogeneous mixture of Oxidizing agent with the water to be treated, as well as one over the conventional methods significantly increased oxygen exchange achieved. This effect is due to the high mentioned Shear frequency and the extreme Pressure alternating stresses caused by the interlocking gripping tools of this rotor-stator machine achieved. This alternating pressure field accelerates the Oxygen exchange processes quite significantly. The Both components are passed through the Bores or tooth gaps of the interlocking Tool rings of this machine at frequencies divided into smallest volume units over 500 Hz, mixed and redistributed. This is achieved that with the very small tool distances of 0.1 to 0.5 mm as in the rotor-stator machine real shears occur.

In addition to improving the oxygenation with an optimal redistribution as procedural advantage, d. H. one in As a result, much improved  biodegradation, there are other advantages like a reduction in plant size or System volume, which is synonymous with lower construction costs or the possibility of one Performance increase in existing systems, which at confined spaces can be particularly important can, and the possible elimination of the otherwise usual Distribution facilities.

When using a gaseous oxidizing agent, preferably air or possibly pure oxygen, the gas in the shear field the rotor-stator machine in extremely small bubbles divided up as not with the known methods are reachable. By the in the inventive The method achieves very small bubbles an extremely large, active exchange area. These very small vesicles are covered with high speed (750 to 7500 revolutions per Minute) rotating tools with the treating water, with constant Interface renewal with a frequency of 1-20 MHz mixed extremely intensely.

In the shear field of the rotor-stator machine constantly new interfaces between air or Oxygen and the water to be treated created and in contact with the unsaturated water Brought gas bubbles. The layer of water that is on the active surfaces of the tools of the Rotor-stator machine is trained immediately Air or oxygen saturated.

The power density (power input / m ³ ) is an important factor in the air or oxygen input. In other words: If the wastewater is exposed to more space with oxidizable material, there is a higher oxygen consumption per unit of volume and time. The size of a sewage system is significantly affected by this. With better oxygen utilization, smaller reaction volumes result and lower investment costs. By using the method according to the invention, existing sewage systems can be used much better.

When using a liquid or an oxidizing agent dissolved in a liquid, e.g. B. hydrogen peroxide (H ₂ O ₂ ) or potassium permanganate (KMnO ₄ ), the method according to the invention offers the advantage of a previously unattainable, intensive mixture of the oxidizing agent with the water to be treated. Due to the constant shear and redistribution under the high-frequency alternating stress in the shear field of the rotor-stator machine, the oxidizing agent is brought into extremely intensive contact with the substances to be oxidized. This results in a very economical use of oxidizing agents while increasing the effectiveness of water purification.

It can be advantageous to use both gaseous and liquid or dissolved in liquids Use oxidizing agents in combination. Here, the high shear forces and the high Redistribution using the rotor-stator machine is achieved for a previously unknown Implementation rate and reaction effect, because on the one hand the gaseous component is very finely dispersed becomes, which leads to a substantial enlargement of the Exchange area leads, and on the other hand a very intensive mixing of the liquid component with the water to be treated, resulting in an essential  Leads to an increase in the oxygen input.

One way to carry out the The inventive method is that total amount of wastewater in the shear field Suspend rotor-stator machine so that the above Fine distribution of the oxidizing agent described in the total volume flow of the water to be treated takes place and that with air, oxygen or a other oxidizing agents enriched or saturated liquid afterwards to the extent possible complete oxidation of the pollutants in the Reaction container is passed. These Process control is particularly suitable for waste water with slimy substances or for highly viscous, too cleaning liquids.

However, it can be beneficial if only one Subset of the water to be treated Rotor stator machine fed and with that Oxidizing agent is mixed, and that subsequently this highly oxygenated mixture the main part of the water to be treated Distribution system in the lower area of a Reaction container is mixed. These The alternative is then used in particular come when it's big, not that high contaminated waste water quantities. The advantage is that a correspondingly smaller Rotor stator machine can be used what lower investment costs and a lower Electricity consumption results; stands opposite however, in the case of new systems for Distribution system necessary effort. This variant but is particularly useful for retrofitting existing sewage systems, the effect of this measure is significantly improved. It can  thus on the one hand both cleaning and improving throughput can also be increased. Secondly, it is this measure makes an existing system possible to be treated with more polluted waste water if necessary. With existing sewage systems, it should be cheap be a specific reaction container To take the amount of water through a pipe, this the oxidants in the rotor-stator machine to mix and this with oxidizing agents or Oxygen loaded beyond the saturation limit Partial quantity in the existing supply line feed.

In the case of new systems, on the other hand, there is one Partial flow of the incoming water to be treated the rotor-stator machine and feed them treated partial stream over a so essential smaller distribution system in the reaction container feed in, while the much larger Wastewater flow directly without Distribution device in the reaction container to be led.

With open reaction tanks, use brings this method still another advantage that namely due to the high oxygen input and the improved effectiveness of the oxidation the high conversion rate and the unpleasant smell can be significantly reduced.

To carry out a procedure of the above A device consisting of a type is suitable Inlet pipe for the wastewater to be treated, one Rotor-stator machine as used in the EP OS 87 10 85 684 is described, a reaction vessel and a device for feeding the Oxidizing agent, the specific arrangement of the  individual components according to the respective Use case is determined.

Usually to be newly built Waste water treatment plants become the supply line for the water to be treated directly with the Inlet connection of the rotor-stator machine and the Outlet nozzle of the rotor-stator machine directly or via a pipeline to the reaction basin connected. In this case d. H. at New installations is the feed of the Reagent both in the feed line as also directly into the rotor-stator machine technically equally suitable.

It is in the case of liquid or in a Reagents dissolved in liquid, possibly the Infeed using an appropriate device to be metered into the feed line to give preference be in the case of using gaseous Oxidizing agents, on the other hand, tend to be the feed directly into the rotor-stator machine.

When feeding directly into the The rotor-stator machine is that of EP OS 87 10 85 684 corresponding or a similar machine with a Device for supplying the oxidizing agent equipped, as for example in DE OS 23 63 888 is described.

An alternative embodiment of the invention Device is that the Rotor stator machine on the inlet side with the Inlet pipe for the water to be treated and is connected on the outlet side to the reaction vessel and the device for feeding the Oxidizing agent opens into the feed line. These  alternative training comes with a particular advantage used in two cases. For one, if it is It depends on the effectiveness of an existing one Increase wastewater treatment plant; that can mean cleaning compared to previous ones Improve condition or existing facility higher or with more polluted waste water to be able to act. Second, in the case larger, but not so heavily loaded Amount of waste water, in which case it is a very effective distribution device like they are known as such.

An example of the method according to the invention and the device for carrying it out is shown in FIGS. 1 to 3 and described in more detail below.

Fig. 1 overall arrangement for large amounts of water

Fig. 2 shear field of the rotor-stator machine

Fig. 3 feeding the oxidant into the rotor-stator machine

Fig. 1 shows an example of an overall system, such as is available for large, relatively low-polluted quantities of waste water, since a relatively small rotor-stator machine is used here. The waste water is introduced into the reaction vessel 1 , which in this case is designed as an open basin, via an inlet line (not shown ) . The water to be treated is removed from the reaction vessel 1 via the removal line 2 and fed to the rotor-stator machine 3 . With the help of a pump 4 , a liquid oxidizing agent is fed into the extraction line 2 via the line 5 . In addition, in this application, air is fed directly into the shear field of the rotor-stator machine 3 with the aid of a conveying fan 6 via the line 7 . The suspension, which is homogeneously mixed with oxidizing agents and saturated with atmospheric oxygen, is fed to a distributor device 9 by means of line 8 .

Fig. 2 shows a partial section through a rotor-stator machine (similar to that shown in EP OS 87 10 85 684) in an embodiment as it is used when the oxidizing agent in the rotor-stator machine in before the water to be treated should be introduced. The stator 11 of the machine is equipped with stator rings 12 and the rotor 14 connected to the shaft 13 with rotor rings 15 , which are also referred to as tools. The rings 12 and 15 provided with teeth or perforations or bores engage in one another, ie in the ring grooves between the rings 12 and 15, and form a meandering shear field 16 in which high shear forces and high-frequency compressive / alternating stresses prevail. The suspension to be treated, enriched with air bubbles or with oxidizing agents, is fed in via the inlet 10 and flows through the shear field 16 of the rotor-stator machine in the direction of the arrow.

In Fig. 3, an embodiment of the direct injection of the oxidant into the shearing field of the rotor-stator machine is shown. The oxidizing agent is pumped by a pump 6 via line 17 into bores 18 of the stator 11 . These holes 18 open into channels 181 a-c of the stator rings 12 , so that the oxidizing agent gets directly into the shear field.

Claims (10)

1. A process for aerobic wastewater treatment by adding an oxidizing agent and mixing the same with the water to be treated, characterized in that water and oxidizing agent to be treated are the shear field of a rotor-stator machine, as is shown, for example, in EP OS 87 10 85 684 are supplied, in which the components are divided into smallest units and mixed intensively under the influence of high shear forces and high-frequency alternating stresses and that during the treatment in this shear field, a high power input per unit volume into the mixture takes place. 2. The method according to claim 1, characterized in that that the oxidant is a gas is preferably air or oxygen. 3. The method according to claim 1, characterized in that it is a liquid or one in a Liquid dissolved oxidant is. 4. The method according to any one of claims 1-3, characterized characterized in that a mixture of gaseous and liquid oxidizing agents is supplied. 5. The method according to any one of claims 1-4, characterized characterized in that the total amount of to treating water of the rotor-stator machine is fed. 6. The method according to any one of claims 1-4, characterized characterized that only part of the to be treated  Water supplied to the rotor-stator machine and with the oxidizing agent is mixed, and that then this with the oxidizing agent or oxygen saturated or supersaturated Mix the main part of the water to be treated via a distribution system in the lower area of a Reaction container is mixed. 7. Device for performing a method according to one of the preceding claims consisting of an inlet line for the waste water to be treated, a rotor-stator machine ( 3 ) as described in EP OS 87 10 85 684, a reaction vessel ( 1 ) and a device for supplying an oxidizing agent. 8. The device according to claim 7, characterized in that the rotor-stator machine ( 3 ) is connected at the inlet to the inlet line for the water to be treated and on the outlet side to the reaction vessel ( 1 ) and the device for supplying the oxidizing agent directly into the shear field the rotor-stator machine ( 3 ) opens. 9. The device according to claim 7, characterized in that the rotor-stator machine ( 3 ) is connected on the inlet side to the inlet line for the water to be treated and on the outlet side to the reaction vessel ( 1 ) and the device for supplying the oxidizing agent opens into the inlet line . 10. The device according to a combination of claims 7 to 9, characterized in that the feed line for the water to be treated opens into the reaction vessel or reaction basin ( 1 ), the rotor-stator machine ( 3 ) on the inlet side via a rotor-stator. machine (3) is on the inlet side via a withdrawal line (2) and the outflow side directly or through a pipeline (8) to the reaction vessel or the reaction tank (1).