DE10245466B4 - Process for the biological purification of wastewater - Google Patents

Abstract

Process for the biological purification of waste water, in which the waste water and gas are fed to a reaction vessel containing microorganisms via a two-fluid nozzle having only two bum-free, concentrically arranged tubes, which is free of additional feed elements and with a vertical axis into the reaction vessel into the reaction vessel Projecting waste water, wherein the inner, the gas-carrying inner tube of the two-fluid nozzle, including a free annular gap of the pumped by a pump discharged wastewater outer tube is enclosed, and in which the mixture of waste water and gas in the reaction vessel moves in a circuit is characterized
- That the inner, the gas-carrying tube (9) of the two-fluid nozzle (2) to which the gas is supplied by means of a blower, with a distance (h) to the outlet opening (3) of the outer, the waste water-carrying tube (8) within the same ends, at least by a factor of "5" greater than the inner diameter (d _F ) of the outer tube ...

Description

The invention relates to a method for the biological purification of waste water according to the preamble of claim 1 (US Pat. EP 0 130 499 B1 ).

at The biological purification of waste water becomes organic pollutants of microorganisms - im hereinafter referred to as "biomass" - under Use of oxygen converted into harmless substances. The wastewater is made by gassing a biomass-water mixture in a reaction vessel cleaned, fed to the continuous sewage and gas and a comparable amount of biomass-water mixture are taken. Under "gas" should air, with Oxygen enriched air or pure oxygen gas understood become.

in the home But also in many industrial processes organically loaded wastewater. For the Purification of such wastewater are Process for eliminating the dissolved organic compounds known aerobically by microorganisms. This procedure are mostly carried out in shallow aeration tanks. The Disadvantages of such methods, such as odor pollution of the environment due high exhaust air volumes, high noise level, greater Space requirements and high investment and energy costs are well known.

It is also known to clean waste water in tall cylindrical towers similar to a bubble column (DE-Z "Chemie-Ingenieur-Technik" 54 (1982), No. 11, pages 939 to 952). Because of the unfavorable hydrodynamic conditions and thus the relatively poor mass transfer conditions of bubble columns whose space load, which is based on the volume of the reaction vessel and the day and measured in COD amount of contaminants, comparatively low. It is about 1 kg COD / m ³ d. The fumigation takes place exclusively at the bottom of each tower used, whereby the specific energy requirement for this process is relatively high.

From the DE 41 05726 C1 For example, a process using a reaction vessel known in the art as a "loop reactor." A loop reactor is a vertical axis cylindrical vessel having in its interior a guide tube which is open on both sides and also vertical In the reaction vessel according to this publication, a two-substance nozzle is arranged above the guide tube, by means of which wastewater and gas are fed in. The gas is fed here via a rectilinear pipe and a surrounding channel to a first mixing section of the two-substance nozzle, which also has an annular channel The first mixing section is adjoined by a second mixing section and a third mixing section, each with a shoulder or an abutment, and an annular channel with suction nozzles is arranged between the second and the third mixing section, via which waste water and gas are sucked in in the third mixing section are mixed with the present in the two-fluid nozzle substrate.

In the method of the DE 198 42 332 A1 in the reaction vessel, which is also designed as a loop reactor, an upper insertion tube and a lower insertion tube are provided, which are separated by a separating plate. The gas is supplied to the reaction vessel via a gassing unit disposed at the bottom of the reaction vessel. In the area of the separating plate, a nozzle consisting of two concentric tubes is mounted, in which liquid conveyed by a pump is discharged downwards into the lower insertion tube. In the process, additional liquid is entrained by this single-substance nozzle.

The likewise designed as a loop reactor reactor after the DE 40 12 300 A1 has as installation a flow tube, in the lower region of a nozzle is mounted, whose structure is not described in the document. Gas is supplied to this nozzle via a first conduit and wastewater via a second conduit. According to the drawings of this document, the nozzle part serving for the gas supply is longer than the nozzle part intended for the waste water.

Also, again as a loop reactor running reactor after the DE 37 03 824 A1 has as installation a guide tube (with deflector) into which a nozzle protrudes far. It has a central bore, a first concentrically surrounding first annular gap for supplying gas and a first annular gap concentrically surrounding the second annular gap with the same axial length. Wastewater to be cleaned is supplied via the central bore and the annular gap. The central bore is axially longer than the gas supply serving first annular gap.

With the method described in the beginning of the EP 0 130 499 B1 Increased turnover in wastewater treatment is achieved. This results in a space load of up to 70 kg COD / m ³ d. Wastewater and gas are introduced in the loop reactor according to this document on a bum-free, concentrically arranged tubes existing two-fluid nozzle in a guide tube. The tube for supplying gas of the two-fluid nozzle lies within the outer pipe serving to supply the waste water. It sticks out of the outer tube. In operation of this loop reactor, loop flow is created around the draft tube with mixing of liquid and gas. Advantages of such a loop flow are a relatively homogeneous flow of the two phases and an associated good transfer of the oxygen required for the wastewater treatment from the gas into the liquid. In this known method, the gas is introduced at the top of the guide tube so that it passes at least once through a complete loop before it can escape from the reaction vessel. However, a high energy input through the liquid supplied to the guide tube is required, so that the supplied and divided into bubbles gas is transported against its "rising struts" with the loop flow down.

Of the Invention is based on the object described at the outset To develop the method so that the Capital expenditure and energy requirements can be reduced.

These Task will be according to the characterizing Characteristics of claim 1 solved.

at This process involves circulating wastewater and the gas of at least one two-fluid nozzle spatially separated from each other supplied the gas being because of the opposite to the outer tube shorter Tube already in the two-fluid nozzle is predispersed. When the mixture of wastewater and Gas from the two-fluid nozzle in the contents of the reaction vessel a momentum transfer arises from which the two-fluid nozzle leaking mixture to the wastewater in the reaction vessel, through which the gas in addition very finely dispersed and transported in the reaction vessel down becomes. By doing so down directed flow the gas-waste water mixture and the deflection of the same at the bottom of the Reaction vessel, arises in the same circulating flow, so that the gas is very evenly distributed in the reaction vessel becomes. A guide tube or a separate dispersing device, such as for example a frequently used ring distributor or a membrane distributor, are not needed in this process. Since the reaction vessel so can be made without separate internals, it can be very simple become. The investment cost is therefore low. Because of the missing Internals can also reduce the energy consumption in this process become.

The Method according to the invention will be with reference to the drawings in embodiments explained.

It demonstrate:

1 schematically an arrangement for carrying out the method.

2 a cross section through a two-fluid nozzle in an enlarged view.

3 one opposite 1 extended arrangement.

In a reaction vessel constructed with a vertical axis 1 is a two-fluid nozzle 2 arranged with a vertical axis, whose more detailed structure made 2 evident. It protrudes into the reaction vessel 1 and, when the process is in operation, into the wastewater. The outlet opening 3 the two-fluid nozzle 2 got off the ground 4 of the reaction vessel 1 a distance A which is greater than half the height H of the waste water in the same. That in the direction of the arrow 5 from the two-fluid nozzle 2 escaping gas-wastewater mixture is in the reaction vessel 1 in the form of dashed circulating flows 6 emotional.

The wastewater to be purified is at 7 an outer tube 8th abandoned, at his in the reaction vessel 1 protruding end part of the two-fluid nozzle 2 is. An inner tube 9 , which at its end also to the two-fluid nozzle 2 belongs, leads 10 abandoned gas. To the reaction vessel 1 is also a pipe 11 connected to the outer tube 8th connected is. About the pipe 11 can waste water from the reaction tank 1 taken and by means of a pump 12 be reintroduced into the cycle together with new sewage in the cycle. The gas becomes the two-fluid nozzle 2 by means of a blower 13 fed. pump 12 and blowers 13 ensure that the mixture of gas and waste water exits the two-fluid nozzle at a sufficiently high speed.

In the two-fluid nozzle 2 are the ends of the pipes 8th and 9 arranged concentrically with each other. 2 shows a preferred embodiment of the two-fluid nozzle 2 , The outer tube 8th surrounds the inner, the gas pipe 9 at a distance, so that there is a free annular gap around it, through which the wastewater can pass. The outer tube 8th is in the area of its exit opening 3 , which is at the same time the outlet opening of the two-fluid nozzle, preferably narrowed. The inner diameter of the inner tube 9 is denoted by d _G , while the inner diameter of the outer tube 8th in the Be rich of its outlet 3 is denoted by d _F. The ratio of d _G to d _F may be approximately between 0.6 and 0.9. It is preferably 0.75. The inner tube 9 ends already in the outer tube 8th , His open end 14 has from the outlet 3 of the outer tube 8th a distance h which is greater than d _F by at least the factor "5".

The method according to the invention is carried out, for example, as follows:
The to be cleaned, over the pipe 8th supplied wastewater (raw sewage) is optionally together with the reaction vessel 1 over the pipe 11 discharged wastewater of the two-fluid nozzle 2 fed. At the same time the two-fluid nozzle 2 over the inner tube 9 Gas supplied. At adequate speed of these two media, by means of the pump 12 on the one hand and the blower 13 On the other hand, can be adjusted, the gas in the two-fluid nozzle 2 predispersed. When the mixture of wastewater and gas from the two-fluid nozzle 2 in the reaction vessel 1 located wastewater creates a momentum transfer from that of the two-fluid nozzle 2 leaking mixture to that in the reaction vessel 1 Wastewater, through which the gas also very finely dispersed and in the reaction vessel 1 is transported down.

Due to the downward flow of the gas-waste water mixture and the deflection of the same on the ground 4 of the reaction vessel 1 , the circulating currents arise 6 so that the gas is very even in the reaction vessel 1 is distributed. The purified wastewater can be the reaction vessel 1 together with biomass via a pipe 15 leave. In a downstream device, not shown here, wastewater and biomass can be separated from each other. The biomass can be mostly via a pipe 16 in the reaction vessel 1 to be led back. The rest of the biomass can be removed as excess sludge.

The outlet opening 3 the two-fluid nozzle 2 is - as already mentioned - in the upper part of the waste water of the reaction vessel 1 , suitably in about two thirds of the ground 4 of the reaction vessel 1 calculated height H of the wastewater. Depending on the height of the mouth of the two-fluid nozzle 2 in the reaction vessel 1 the gas is blown by means of the blower 13 more or less compacted. An amount of gas corresponding to the supplied gas may be the reaction vessel 1 over a line 17 leave.

As the ratio of height to diameter of the reaction vessel 1 and the velocities of the waste water and the gas in the two-fluid nozzle 2 For fluid dynamic reasons certain values have to be met and because the overall height of the reaction vessel 1 is limited for energy reasons, be useful for large amounts of waste more two-fluid nozzles 2 with appropriate supply lines in a reaction vessel 1 arranged. This is for example for three two-fluid nozzles 2 in 3 shown. The installation of several two-fluid nozzles 2 in a reaction vessel 1 has the additional advantage that the dispersion of the gas supplied by a bouncing effect of the deflected and colliding fluid flows is further enhanced.

Claims (4)

Process for the biological purification of waste water, in which the waste water and gas are fed to a reaction vessel containing microorganisms via a two-fluid nozzle having only two bum-free, concentrically arranged tubes, which is free of additional feed elements and with a vertical axis into the reaction vessel into the reaction vessel Projecting waste water, wherein the inner, the gas-carrying inner tube of the two-fluid nozzle, including a free annular gap of the pumped by a pump discharged wastewater outer tube is enclosed, and in which the mixture of waste water and gas in the reaction vessel moves in a circuit characterized in that - the inner tube carrying gas ( 9 ) of the two-component nozzle ( 2 ), to which the gas is supplied by means of a blower, at a distance (h) from the outlet ( 3 ) of the outer pipe carrying wastewater ( 8th ) within the same, at least by a factor of "5" greater than the inner diameter (d _F ) of the outer tube ( 8th ) in the region of the outlet opening ( 3 ), and - that the outlet opening ( 3 ) of the outer tube ( 8th ) and thus the two-fluid nozzle ( 2 ) from the ground ( 4 ) of the except the two-fluid nozzle ( 2 ) no further internals containing reaction vessel ( 1 ) has a distance (A) greater than half the height (H) of the in the reaction vessel ( 1 ) is located wastewater. Method according to claim 1, characterized in that the outlet opening ( 3 ) of the outer tube ( 8th ) and thus the two-fluid nozzle ( 2 ) at about two-thirds of the height above the ground ( 4 ) of the reaction vessel ( 1 ) disposed wastewater is arranged. Process according to claim 1 or 2, characterized in that the waste water is discharged to the outer tube ( 8th ) of the two-component nozzle ( 2 ) together with from the reaction vessel ( 1 ) is discharged wastewater. Method according to one of claims 1 to 3, characterized in that in a reaction vessel ( 1 ) two or more two-fluid nozzles ( 2 ) are arranged without any other installations.