DE2455633B2 - Method and device for killing germs in wastewater - Google Patents

Description

The invention relates to a method for killing germs in wastewater by means of ozone and Ultrasound after mechanical and chemical removal of impurities as well as on a device for ozonizing wastewater.

In one known from DT-PS 855521 The wastewater is not only processed with ultrasound, but also treated with ultraviolet radiation to kill the germs while the optional additionally provided introduction of an oxygen-containing gas into the sewage the germicidal effect unaffected. In this known method, the actual killing of the germs causing ultraviolet rays are better absorbed because of the ultraviolet energy in the Pressure fluctuations caused by wastewater, the rays otherwise smoothly passing through it partially refracted and reflected. Since in this known method through the wastewater any ozone passed through does not improve the killing of germs compared to the caused by the effect achieved by the ultraviolet rays, this may have the germicidal property of ozone cannot be applied successfully.

Numerous methods and devices are known in connection with the purification of wastewater, in those with the help of mechanical vibrations and additives, such as so-called flocculants and ozone, a mechanical and chemical removal of contaminants from wastewater is possible.

From DE-OS 1642 387 a device for

jo ozonizing wastewater is known to be one used lower and an upper section having tower, in the lower section of a device for introducing ozone into the wastewater. The inlet for the wastewater is also

s ^r > if provided in the lower section of the tower. While the lower section of the tower forms a free space for the sewage, the upper section of the tower is filled with a filler material. This known device is used to break down the proportions of strongly smelling or harmful substances contained in the wastewater, such as. B. Phenol, with the help of the discharged into the wastewater ozone. In contrast, it is not intended to kill germs in the wastewater. The object of the invention is to develop the method of the type mentioned at the outset in such a way that optimal killing of germs is achieved with the aid of ozone introduced into the wastewater. Furthermore, a simple device for carrying out this method is to be created.

In the case of a procedure of the type mentioned above This object is achieved according to the invention in that one is more effective by sound energy in the area Concentrations of ozone creates cavitation in the water, with the downward flowing wastewater zones

v> passes through with increasing ozone concentration and sound energy.

The method according to the invention is characterized by this from that in zones with a sufficient ozone concentration to kill germs in the

to wastewater such a great sound energy is introduced, that cavitation occurs, whereby a previously unknown increase in the germicidal effect of the Ozone is reached in the wastewater. The wastewater flows z. B. in a preferably vertical

h ^r > water column downwards, with ozone and sound energy being introduced into this water column from below. The wastewater flowing down the water column therefore reaches it after a certain pretreatment

with ozone and sound energy a zone in which cavitation occurs due to the sound energy, in this one Zone also has a sufficient concentration of ozone to kill germs. Even when it reaches this zone, the wastewater can have even higher ozone concentrations and sound energies get abandoned. It could be proven that the sound energy in the wastewater caused cavitation a considerable increase in germ-killing. '. ilen effect of ozone causes that in its absence of sound energy or a sound energy level that is too low, which is not yet cavitation causes in the wastewater would occur.

According to a preferred embodiment of the invention, the sonic treatment is carried out in two different frequencies, the lower frequency not exceeding 30 kHz and the other Frequency is at least twice as high. Because of these different frequencies, there is a wider range of species of germs in the sewage, since it has been found that different types of germs also react to different high frequencies.

According to a further development of the invention, the wastewater is treated acoustically for sound treatment Energy so that it is not reflected to the sound source. This will damage it or even Destruction of the sound sources is also reliably avoided, when the sound energy required in the wastewater to achieve cavitations is relatively high is.

A device for ozonizing wastewater with a several sections one above the other Tower having an inlet and outlet for the sewage and in its lower section a device for introducing ozone, is thereby for carrying out the method according to the invention characterized in that in the lower section at least one device for introducing ultrasonic energy is provided and that the outlet for the treated waste water in the lower section and the inlet are located at the top of the tower.

With the aid of this device, the method according to the invention is particularly simple and effective perform, as the wastewater in the tower is essentially perpendicular to the bottom in countercurrent the rising ozone and the sound energy flowing upwards.

According to a development of the invention, this device is designed so that the upper section open lower section through an opening which is small compared to the diameter of the tower provided horizontal partition is divided into two parts, that in the upper of these parts a first Means for introducing ultrasonic energy of a relatively low first frequency and a first Means for introducing ozone are arranged and that in the opposite of the upper soundproofed lower of these parts a second device for introducing ultrasonic energy one opposite to the first at least twice the frequency and a second device for introducing ozone are arranged.

This design of the device means that it flows downwards from the upper section to the lower section Wastewater with the rising, from the first facility for introducing ozone emitted ozone and that emitted by the first device for introducing sound energy Sound energy pretreated and finally in the zone where cavitation for the first time due to the sound energy in the wastewater occurs, treated to kill the germs. The ones from the upper part of the lower Part of the funky energy and that too The ozone given off by this part can therefore move freely upwards into the upper part of the tower Spread out section. After that, the sewage flowing downwards passes through the opening, which is relatively small Cross-section in the lower part of the lower section, which is soundproof from the upper part is and only negligibly small amount of the second device for introducing ozone given off ozone to the upper part of the lower section. This is in the essence closed part of the lower section a high ozone concentration and also sound energy reach to effect a final treatment of the wastewater. Due to the sound insulation between the The upper and lower parts will deliver acoustical energy to the upper part of the lower section and thus also the upper section of the tower prevented and at the same time a mixture of prevents different frequencies of sound energy in the upper part. Even with the same Discharge of ozone by the two facilities for discharging ozone into the sewage and also an introduction of the same sound energy by the two devices for introducing sound energy are in the lower part of the lower section

jo larger concentrations of ozone and a larger one Achieve sound energy as this is within a substantially closed and relatively small Stay locked in the room.

According to a further embodiment of the invention

r> is the radiation area of the device (s) for discharging of ultrasonic energy arranged at an angle to the inner surface of the tower. Through this it is ensured that the sound waves reflected on the inner surface of the tower do not fully affect the

4 (i radiation surfaces of the devices for discharge of ultrasonic energy, causing possible damage when large ultrasonic energy is applied is safely prevented in the wastewater.

4 ^r > An embodiment of the invention is explained with reference to the drawing. It shows

1 shows a schematic plan view of a wastewater purification plant using the device according to the invention,

Fig. 2 is a side view of a tower used in the device,

Fig. 3 is a section along line 17-17 in Fig. 2; Fig. 4 is a view, partly in section, showing the Shows arrangement of ultrasonic radiators used in the tower, and

FIG. 5 shows a plan view of a holding plate for the ultrasonic emitters shown in FIG. 4.

A wastewater treatment system 10 shown in Fig. 1 comprises a wastewater supply line 12 in which a Zer-

bo smaller 14 is arranged, a compensation tank 16, a settling basin 18, a flocculation basin 20, a clarifying basin 22, a collecting basin 24, a filter system 26, an (ozonization sound) tower 28, an ozone contact basin 30, a dwell basin 32

bs and a sewer pipe 34. The sewage flows one after the other in the specified sequence through the system.

The system shown in Fig. 1 is designed.

that it can purify around 2.3 million liters of domestic wastewater flowing into it every day. After processing by the shredder 14, the waste water supply line releases the waste water into the equalization basin 16 , which compensates for inflow peaks and uneven degrees of contamination, so that the rest of the system treats waste water with an approximately constant quality.

As can be seen from Fig. 1, the compensation basin 16, the settling basin 18, the flocculation basin 20 and the clarification basin 22 are all rectangular in plan and have common walls between them that serve as weirs so that waste water from one basin overflows into the adjacent basin can. However, a wall 54 separating the basins 16 and 18 does not have this function. The wastewater coming from the equalization basin 16 is drawn off through a suction line 46 with a pair of pumps 56. The outlet 60 of the pumps 56 discharges the waste water into a weir 62. Before being fed into the weir 92, however, a suitable coagulant is metered into the outlet 60 so that many initial flakes are formed in the settling basin 18 while the waste water is held in this settling basin. The coagulant can be a known coagulant, for example alum, ferrous chloride, ferrous sulfate, aluminum chloride.

As can be seen from Fig. 1, the bottom of the sedimentation basin is in the shape of an inverted pyramid to create a collection area 66 for removing sludge.

The waste water from the settling basin flows together with the initial flakes carried along from the settling basin via a semi-cylindrical partition 78 which is mounted on a wall 80 between the settling basin 18 and the flocculation basin 20. In the space between the wall 80 and the partition 78, a pipe 82 is arranged, which serves to feed a polyelectrolyte into the waste water, which forms large, heavy flakes from the initial flakes. The internal shape of the flocculation basin 20 is essentially the same as the shape of the settling basin 18 so that a collecting area 92 is formed. The wastewater and the flakes carried along flow through an underwater weir 112 into the clarifier 22 between a wall 116 and a partition 118 which runs downwards from above the surface of the liquid in the clarifier. This ensures that all of the wastewater flowing from the flocculation basin into the clarifier must first flow to the lower section of the clarifier so that it can flow under the lower end of the partition 118 . This creates a floc cover beneath the bottom of a plate structure 122 which separates the flocs from the liquid. The clarified liquid flows through the top of the plate structure 122 and through an outlet tube 124 in a wall 126 between the clarifier 22 and the sump 24. Thus, the liquid in the sump 24 will have a very low level of entrained solids and the solids remaining only a very small particle size, since larger and heavier particles were removed from the plate structure 122.

The collecting basin 24 serves as a reservoir for the clarified liquid which is pumped through the filter system 26, the tower 28 and the ozone contact basin 30, for which purpose pumps 132 are provided for drawing off the clarified liquid from the collecting basin 24.

The clarified and filtered liquid is passed through the tower 28 from the outlet of the filter system 26. A considerable increase in the effectiveness of the ozonization sonication tower has been found when it is combined with a sewage treatment system as described here. This arises from the fact that the particles

ίο which is particularly suitable for this Ozonisations sound reinforcement treatment in the waste water, the treated Ozonisations the sound reinforcement tower, have a size and composition so that their. Effectiveness is greatly increased.

Depending on the type of wastewater treated and its throughput volume, in certain cases the wastewater may not be completely free of germs when it emerges from the tower 28. For these cases, the ozone contact basins 30 are provided, through which the waste water flowing out from the tower 28 flows for the purpose of further ozonization, so that sterility of the liquid flowing out of the system into the residence basin 32 is ensured.

Ozone for the ozone contact basins 30 and the tower 28 is generated by an ozone generator 152 which can convert air or oxygen into ozone.

The feeding of ozone into the tower 28 and

foam in the ozone contact basin 30 , which contains ozone, rises to the top of the tower 28 and the ozone contact basin 30. This foam can be withdrawn from the upper end of the tower 28 by means of a foam discharge line 154. The tower 28, which is shown in more detail in FIGS. 2 to 5, forms the device for carrying out the method for killing germs.

The tower 28 is formed from a long, cylindrical tower which has a top 302 with an opening 304 located therein, the bottom of the tower 28 standing on a suitable base chamber 306 , which seals the bottom of the tower and provides a space for those still to be described Devices forms. The upper opening 304 serves as an outlet for drawing off foam which can be generated by the ozonization and sonication of the treated wastewater.

An inlet 308 for the inlet from the filter system 26 is provided in the wall of the tower 28. The tower is also provided with an outlet 310 near its bottom, the outlet opening leading to the ozone contact basin 30 if this is still required. Otherwise it can lead directly to the retention basin 32 or to the final outlet of the plant. For ease of manufacture and maintenance of the tower can be constructed 312 and 314 28 of an upper and lower portion which are connected by means of flange connection egg ner 317th The upper portion 312 serves essentially as a conduit for the entering through the inlet 308 from water flowing through the tower down. However, as is still stated, the wastewater flowing through the upper section 312 is also exposed to both acoustic energy and ozone, for the purpose of pretreatment before the wastewater reaches the zone of maximum ozonation and sonication in the vicinity of the ozone generators and ultrasonic emitters, which will be described later. For ease of manufacture and maintenance, the lower section 314 is made up of three separate sections 316, 318 and 320 to facilitate the installation of the ultrasonic

emitters and ozone generators in the lower section 314 is easier.

In the case of the tower 28, ultrasonic emitters or emitter groups are used, which are identified by the reference numerals 322 and 390 are designated. The ultrasonic emitters 322 preferably operate at a relative rate low frequency, for example of about 20 kHz, which is just in the ultrasonic range lies. Preferably four ultrasonic emitters 322 are provided, which are magnetostriction transducers acts. As best seen in Figure 4, the ultrasonic emitters 322 are exposed on four Faces 324 of a rhomboid-shaped holding frame 326 mounted, with the surfaces from the outer sides formed by four panels 328 which make up the frame. The panels are at their top and lower ends connected by means of U-profiles 330. The rhomboid-shaped holding frame 326 is mounted within the wall of tower 28 and with it between sections 316 and 318 connected by means of a retaining plate 332, which is between flanges 334 and 336 at the bottom of the section 316 or at the upper end of the section 318 is held. The flanges are with the help of no connected bolt. The holding plate 332 can be seen in FIG. 5 and has a substantially circular circumference and is considerable with numerous bolt holes 335 and a central opening 337 Size provided. The opening 337 is preferably shaped so that it has two parallel edges 338 and 340 which are rectilinear and have a pair of curved end edges 342 and 344 which are concentric to the outer edge of the retaining plate, with the curved end edges between the ends of the Edges 338 and 340 run. A pair of retaining plates 346 and 348 are welded to the edges 338 and 340, wherein the retaining plates are perpendicular and essentially the same as the retaining frame 326 are shaped. The holding frame is welded to holding plates 346 and 348. The ultrasound tracer 322 are on the four surfaces 324 of the holding frame, for example with the aid of not shown Bolt, mounted. The ultrasonic radiators and the opening 337 together with the holding frame such dimensions that around the ultrasonic radiator and through the opening 337 a large There is passage for the downward flowing liquid so that it does not have any significant hindrance can flow through. Proper placement of the ultrasonic emitters 322 avoids the use of sound energy is reflected from the wall of the tower back to the ultrasonic emitters 322 as such a reflection could possibly damage or destroy the ultrasonic emitters.

Energy must be supplied to every ultrasonic emitter. Each ultrasonic emitter is therefore provided with a line 350 (FIG. 4) which leads from an inlet opening 352 in the wall of the tower 28 to an opening 354 in the ultrasonic emitter itself. Conductors from an ultrasonic generator outside the tower 28 to input connections of the ultrasonic emitter 322 go through the line 350. As already mentioned, the ultrasonic generator for the ultrasonic emitters 322 preferably operates at a frequency of approximately 20 kHz.

The tower 28 is designed so that the sonication takes place before or at the same time as the ozonization. As will become clearer in the following, two separate locations are provided for the supply of ultrasonic energy, namely, on the one hand, by means of the ultrasonic emitters 32 and, on the other hand, by means of the ultrasonic emitters 390, which will be described later. Below the ultrasonic emitter 322 there is an ozone generator 356, which can be of any type. Presently, preference is given to the known porous stone construction, which is also shown. The ozone generator 356 is made of a diametrically extending

ι »Tube made of porous stone, denoted by the reference number 358 is designated. The inlet for tube 358 is in the form of a nipple 360 (Fig. 3), which extends from the inlet end of the porous tube 358 to a mounting flange 362. On the outside

There is a second one of the fastening flange 362 Nipple 364, which leads to a suitable connection piece, which here is in the form of a flange 366 and is connected to an ozone supply line 368 (see Fig. 2). The ozone generator isn't here shown in more detail. For reasons of mechanical rigidity, the opposite end to the inlet end can be used End of the tube 358 may be provided with a support rod or a support tube 370, which is attached to a suitable Fastening flange 372 is attached, which is arranged diametrically opposite the fastening flange 362 is.

Numerous such porous ozone donors can be arranged in any desired pattern.
Below the ozone generator 357 there is one

with an opening provided plate 374, which largely separates the section 320 of the tower 28 from the rest of the tower. This plate 374 is inserted between the flanges 376 and 378 at the bottom of section 318 and at the top of section 320, respectively. It is held there by means of screws (not shown). The plate 374 is provided with the relatively small, central opening with a diameter of the order of magnitude of approximately 10 cm, through which a small elbow pipe 379 with a diameter of 10 cm also passes, through the wedge of liquid flowing down through the bottom of the section 318 flows into the section 320, the liquid being conducted away from the outlet 310 so that a certain residence time of the liquid in the lowermost section 320 of the tower 28 is ensured. A second ozone generator 380, which can be identical to the ozone generator 356 and is preferably mounted in the same way, is arranged at the bottom of the section 320. Several ozone generators can also be provided here. Immediately below the ozone generator 380 is a membrane 382 which forms the bottom of the tower 28 and the upper end of its base chamber 306 and which is held mechanically by flanges 384 and 386 at the base of the section 320 and the upper end of the base chamber 306 , respectively. Numerous ultrasonic radiators 390 with a relatively high frequency are arranged within the hollow base chamber 306 in such a way that their radiating surfaces lie against the membrane 582 or are mechanically coupled to it. These ultrasonic emitters are preferably piezoelectric transducers which are set so that they emit an output oscillation on the order of 85 kHz or more. These ultrasonic emitters 390 are arranged within the base duct without contact with the flowing liquid. Since the ozone generator 380 is arranged very close to the vibrating membrane 382 , the elbow tube 379

and liquid later flowing out of the outlet line 381 previously subjected to simultaneous ozonation and sonication at high frequency.

The tower 28 described above has a number of desirable properties. The most striking of these is that the entire tower works on the countercurrent principle, which significantly increases the effect of ozonization and sonication of the liquid. This means that the liquid, as it moves from inlet to outlet, continuously encounters ever higher concentrations of ozone and ultrasonic radiation, especially those of lower frequency, and this ever increasing concentration of ozone and acoustic energy has an ever increasing influence the oxidation and killing of germs of the liquid flowing through the tower. In addition, the tower 28 uses two separate stages of ozonation and sonication with two different sound frequencies. The reason for using different sound frequencies in the two sections is that certain substances or germs, small organisms and their eggs are more sensitive to one frequency than to another, so that by using different frequencies a larger range of substances can be effectively used with sound energy treated and made more sensitive to ozone treatment.

For a system with a throughput of approximately 2.3 million liters per day, as described here, the inner diameter of the tower 28 is approximately 61 cm and the total height of the tower including the base chamber of approximately 25 cm is approximately 610 cm. The residence time of the liquid in the tower is approximately two and a half minutes. The power absorbed by the ultrasonic emitters 322 is approximately 4000 W, ie approximately 1000 W per ultrasonic emitter 322. The power absorbed by the ultrasonic emitters 390 is approximately 4800 W, ie approximately 200 W per ultrasonic emitter, since the system described has an arrangement of 24 such Ultrasonic emitters located in the base chamber 306. It is essential that the ultrasonic emitters are operated with these powers so that cavitation is generated in the liquid flowing through the tower for treatment.

The amount of ozone to be used in the tower 28 largely depends on the type of sewage flowing into the tower and the legal requirements for the quality of the sewage flowing out. In the case of a combination of ordinary household wastewater which has been treated in the manner described above before being fed into the tower 28 , it has been found that an amount of ozone of between one and ten parts per million of treated wastewater is sufficient to achieve a satisfactory result. Exceptionally good results have been achieved with pretreated household sewage when approximately two parts per million of ozone are introduced into the tower, and preferably one part per million from each of the two ozone generators. In general, however, this means that if only small amounts of ozone are introduced into tower 28 , an ozone contact chamber will likely be required since it has generally been found that approximately six to fifteen parts per million of wastewater is required to ozonate the entire facility, to achieve the required degree of oxidation and germ killing. However, when higher concentrations of ozone are used in tower 28 , less or no ozone is required in an ozone contact basin, eliminating the need. As an alternative to the use of ozone contact basins, additional towers 28 can also be used in series, so that the particular advantage of sonication before or with the ozonization is retained.

List of reference symbols

10 Sewage treatment plant 12th Waste water supply 14th Shredder Ii 16 Equalizing basin 18th Settling basin 20th Flocculation basin 22nd Clarifier 24 Reservoir 20th 26th Filter system 28 tower 30th Ozone contact basin 32 Linger basin 34 Sewage discharge 25th 46 Suction line 54 Wall 56 pump 60 Outlet 62 Weir 30th 66 Collection area 78 Septum 80 Wall 82 pipe 92 Collection area 35 112 Underwater weir 116 Wall 118 Septum 122 Plate structure 124 Outlet pipe 40 126 Wall 132 pump 152 Ozone generator 154 Foam discharge line 302 Top 45 304 opening upper 306 Base chamber 308 Inlet 310 Outlet 312 upper section 50 314 lower section 316 section 317 Flange connection 318 section 320 section 55 322 Ultrasonic emitter 324 area 326 Holding frame 328 plate 330 U-profiles b0 332 Retaining plate 334 flange 335 Bolt holes 336 flange 337 opening b5 338 edge 340 edge 342 End edge 344 End edge

346 Retaining plate 348 Retaining plate 350 Line 352 Inlet opening

354 opening 356 ozone generator 358 porous tube 360 nipple 362 mounting flange 364 nipple 366 flange 368 ozone supply line

24 55 633 Holding tube 370 Mounting flange 372 plate 374 flange 376 flange 5 378 Knee tube 379 Ozone generator 380 Outlet pipe 381 membrane 382 flange ίο 384 flange 386 Ultrasonic emitters 390 For this purpose 3 sheets of drawings

Claims (6)

Patent claims: 1. Method of killing germs in wastewater by ozone and ultrasound after mechanical and chemical removal of contaminants, characterized in that one Generates cavitation in wastewater through sound energy in the range of effective ozone concentrations, the downward flowing wastewater zones with increasing ozone concentration and sound energy passes through. 2. The method according to claim 1, characterized in that the sound treatment at performs two different frequencies, the lower frequency not exceeding 30 kHz and the other frequency is at least twice as high. 3. The method according to claim 1 or 2, characterized in that one is used for sound treatment supplies acoustic energy to the wastewater in such a way that it is not reflected back to the sound source. 4. Apparatus for ozonizing wastewater with a tower having a plurality of sections one above the other which has an inlet and outlet for the wastewater and in a lower section a device for introducing ozone, for performing the method according to one of claims 1 to 3, characterized that in the lower section (314) at least one device (ultrasonic emitters 322, 390) is provided for introducing ultrasonic energy and that the outlet (310) for the treated wastewater in the lower section (314) and the inlet (308) at the top of the tower ( 28) are arranged. 5. Apparatus according to claim 4, characterized in that the lower section (314 ) open to the upper section (312) through a horizontal partition (plate 374) provided with an opening (elbow tube 379) which is small compared to the diameter of the tower (28) two parts (sections 316, 318; 320) is divided, that in the upper part (sections 316, 318) a first device (ultrasonic emitter 322) for introducing ultrasonic energy of a relatively low first frequency and a first device (ozone generator 356) for introducing Ozone are arranged and that in the lower part (section 320), which is sound-insulated from the upper part, a second device (ultrasonic emitter 390) for introducing ultrasonic energy of at least twice the frequency of the first and a second device (ozone generator 380) for introducing ozone are arranged. 6. Apparatus according to claim 4 or 5, characterized in that the radiation surface of the device (s) (ultrasonic radiators (322, 390) for introducing ultrasonic energy is arranged at an angle to the inner surface of the tower (28).