DE2953063C1 - Device for aerating and circulating waste water - Google Patents

Description

3 4

Liquid enters The air vesicles 24 are required for oxygen distribution like afterwards

due to the turbulence generated by the propeller, also for minimal cleaning speeds (scou-

xeilL In this way, the aerator 10 from the propel ring provides velocities), such as 0iI22 to 0) 152 m / sec (0; 4 to 0.5 ft /

ler type for aeration during a fountain. see, or fpisjy worry. Earlier ventilation systems require

As will be explained in more detail below, 5 derteri can produce at least 3.7277 watts (ft5 hp) per 28.32 rii ³

Aerator i0 to create a directed flow (1000 ft ³ ) or 13.16 watts per cubic meter of water and

be built, the aerators 10 are insultiert so that higher power densities to achieve such flow

they are additive to the uniform, one complete movement velocities.

bordering water bodies capturing mixed patterns on the one hand, the effindurigsgemiges ancestors achieved

wear. Thus, a flow of liquid can be directed to an appropriate injection of oxygen into the wastewater and

and circulation patterns are created to otherwise desirable mixing of the aerated sewage

Velocity vectors over an entire volume at appropriate power levels. The present-

to ensure a body of water to be treated, the invention enables setting up or control

The inner tube 16 has a line 26 with oxygen injection and mixing speeds drawn longitudinal axis. The aerator 10 is in the wastewater 15 at efficient levels of performance among numerous swaths a platform or carrier 28 is held. The service for cleaning conditions. The procedure includes Aerator 10 is in any conventional manner, such as the steps of providing a plurality of aerators a bracket 30 attached to the plate form 28 tern of the propeller type, each ventilator being a hollow one The aerator 10 is held in the sewage so that the pipe with opposite ends and a zwi-longitudinal axis 26 an angle between 12 and 25 degrees 20 see these ends extending longitudinal axis as well forms with the horizontal preferably has a propeller adjoining one of the ends Angle set to 22 degrees. In this way, the aerator 10 is specific to the present method The aerators are in a limited capacity due to the rotating propeller Mixing energy to a circulation and flow arranged over a volume of water, such as a basin or a to produce a larger area than it would for the inner lagoon, with the propeller and the attached to it Conventional turbine aerator is typical when the adjacent pipe end is below the top surface Angle greater than 25 degrees is made so that that of the water is located and having a longitudinal axis of one Tube 16 becomes more vertical, at the expense of the mini, each aerator is at an angle to the hose to a certain extent a higher oxygen rizontal is inclined. The water is thereby passed over If the angle is less than 12 degrees 30 mixes that the aerator in a corresponding opposition the horizontal is made, the position is so arranged and operated that one-mixing Process at the expense of oxygen transfer discrete circulating flow patterns around each of the augments It was found that the inclination fan and the individual flow angles are generated the range of 12 to 25 degrees is an optimal most connected to a larger, ge-compromise to form a closed overall flow pattern between mixing and venting 35. That represents and that the angle of inclination of 22 degrees means that the fans are arranged so that then, It is preferable if the propeller of the aerator is large enough

The inventive method has its main speeds to be driven to ambient air in

neuter use at aerated lagoons or to inject the water to each of the aerators individual

Basins that are created as part of an overall sewage treatment 40 flow patterns that interrelate

management process can be used. Ventilated lagoon sy- stems are used to create a larger, closed flow

Stars can be used to form an overall pattern for three different mixing levels.

be true. Mixing levels are generally determined by the individual flow patterns and the chaining The degree of contamination in the water or the BOD requirement of adjacent individual flow patterns are shown in FIG. 4th destined for most waste water treatment 45 shown There are schematically three aerators 10A, Lung lagoons showing relatively dilute domestic wastewater 1OB, IOC. Horizontal flow vectors that received, which is called a horizontal flow of water to meet the oxygen demand, are around Required performance for most of the year for each of the aerators 1OA 105 and 10 starting from this significantly less than the power required to hold. A plurality of forward-facing Solids in suspension is required The low-50 horizontal flow vectors 32 denotes a The first power supply level must have sufficient acidic substance from the propeller of the aerator 10A to the front transfer, in order to meet the demand, the killing horizontal liquid flow. Negative horizon the BOD value in the wastewater. There is a valley flow vectors 34 denote a horizontal ventilation typically that for a transfer of 0.318 to the valley of liquid flow from the area behind the 0.635 kg (0.7 to 1.41b) oxygen per 0.454 kg (1 lb) 55 propellers drawn to the propeller of the aerator 10A BOD is sufficient. A medium level of power will be. Horizontal flow vectors 36 denote input must for a uniform oxygen distribution diffuse horizontal liquid flow, that of care over a lagoon or basin volume, the forward-facing and flow curve namely in addition to a mere supply of a stream designated gates 32 is bent backwards certain amount of oxygen. Thus, an additional 60 and is associated with the negative flow vectors 34 before power is required for that which connects the required electricity or a part of it is to inject oxygen only, so that forms are similarly named flow vectors minimal circulation effects are generated, around a well represented by the ventilators loß and ioc. Like it uniform distribution of oxygen over a range of F> g. 4 it can be seen, are the aerators 1OA, 1OZ? and ensure volume of funds. In the case of such an average IOC, they are arranged in relation to one another in such a way that they move backwards However, no level is used to hold solids at least part of the flow through the negative flow vekin Suspension creates sufficient turbulence. The gates 34 designated stream from one of the aerators highest power input level that could reasonably be expected to work with at least a portion of the forward-facing

5 6

Flow vectors 32 of an adjacent aerator are also the mean speed of the closed

In this way there is a horizontal gene flow pattern in the basin. Since overall

total power in the general forward direction using a total of 26.839 kW (36 hp) in the first pool

Flow vectors 32 generated. and since this has a volume of about 7.787 m '

Figs. 2A and 2B show a plurality of air vents (275,000 cu ft) has the mean pelvic speed

tern 10 of the propeller-type that using platforms or speed of 0.235 m / sec (0.77 fps)

Booms 28 in a pair of wastewater treatment of 96.92 watts per 28.32 m ³ or 3.42 watts per cubic

Basins are kept in which investigations of the meter of water reached. The second basin also has

lying invention can be carried out. Flow a volume of about 7,787 m ³ (275,000 cu ft), and thus

vectors or arrows 40,38 denote a closed io a mean pool speed of 0.177 m /

An overall horizontal flow pattern or lake (0.58 fps) in the second basin using _r

corresponding flow path of the wastewater. The au- of 52.19 watts (0.07 hp) per 28.32 m ³ (1000 cu ft) or ..

ßere sate of circularly arranged aerators 10 1.84 watts per cubic meter of water achieved in the ^

generated the second basin used by the flow vectors 38, 14.91 kW (20 hp) led to gf

nete overall flow pattern. That through flow is a velocity sufficient to move solids into |

vectors 40 denoted current sea seam pattern will maintain a complete suspension. ||

by an inner sate of circularly arranged When a 3.728 kW (5 hp) aerator from the propeller- <pt

Aerators 10 generated that used by the flow vectors type and about 22 degrees opposite the horizon- ^

40 is arranged as a total flow pattern circulates inclined in the valley, one extends to the \!

the direction indicated by the flow vectors 38 20 hold solids in suspension sufficient HO- i,

Overall flow pattern. Rizontal flow at least 60 ft (183 m) forward, ;; |

The F i g. 2A and 2B show a plan view of two lagu and it becomes a diffuse flow field with a width <

nes or basins that formed part of a sewage treatment system of approximately 183 m (60 ft) if a 1,491 kW

Formation system in which the present process (2 hp) uses propeller-type aerators and below

is practiced. The water treatment system contains 25 an angle of inclination of about 22 degrees

Also a primary sedentation unit, a coarse fil- the horizontal is arranged, extends a v

ter (roughing filter) and! a clarifying agent, according to which a tank is sufficient to keep solids in suspension-; -.;,

ken- or lagoon system with four basins follows, with the horizontal, forward-facing flow field 3

Figures 2A and 2B correspond to first and second at least 9.14 m (30 ft) forward, and a diffuse; «i

Show the pelvis of the pelvic system. Each of these first 30 flow fields has a width between about 9.14 m and;

two pool has a surface area of approximately 12.19m (30and40ft). j

0304 hectares (0.75 acres) and a volume of water It is generally noted that an average ge,

approximately 7.787 m ³ (275 300 approx ft). The pools have a speed of 0.152 m / sec (0.50 fps) sufficient i _L

Width of about 53.34 m (175 ft) and length of should be to remove solids in a sewage treatment J ₁

about 57 91 m (190 ft). 35 to keep the treatment device in suspension. The higher j;: v

The basin from FIG. 2A has a multitude of loading performance in the first basin has been increased because of the S ₁

fans 10 of the propeller-type used with an overall BOD loading of the basin system Like it;

power of 26.839 kW (36 hp) are installed. That was mentioned in before, those in the basins took care of the

F i g. The basin shown in FIG. 2B has a plurality of areas. 2A and 2B achieved mean pelvic speed ;;

fans 10, with a combined power of 40 times that the solids are completely in sus- γ

14.91 kW (20 hp) are installed. The boom 28 retirement were retained. It also falls within the framework ^

extend approximately from the middle of each side of one of the present invention, smaller flow |,

inward of each pool. Each of the external aerators should be used at speeds where solids only ||

are partially suspended or levitated at a distance of approximately 30 feet (9.014 m) from any. ^

corresponding side wall and each of the 45. However, the present invention is intended to provide |!

inner aerator is at a distance of approximately mean pool speed of more than 0.076 m / |

See 183 m (60 ft) from a corresponding sidewall (0.25 fps) for the purpose of mixing the sewage. ^

^{In the} preferred embodiment, a Bek- |

Fi g. 3A shows a profile or vertical cutting speed greater than 0.152 m / sec (0.5 fps) | through the basin from FIG. 2A along the line between SE 50. An average pelvic speed of more. _v ; and NW running foot line 195. F ϊ g. 3B shows a as 0.152 m / sec (0.5 fps) should be sufficient to get fixed- | ^a h "! ^; " hes profile "of a vertical section long to keep the fabrics completely in suspension. f: foot line 195 running between SW and NE in the basin shown in FIGS. 2A and 2B in FIG. 2B Figures 3A and 3B were oxygen at a rate greater than 0307 kg, specifying the velocity measurements results in m / 55 (2.0 lb) oxygen per 745.54 watts (1 hp) and 1.229 g, respectively _SE see (ft / sec or fps) at different depths in the per watt hour injected The measured velocities from FIG Rate of large to a mean linear G. Speed greater than the first value At the 0.235 m / sec (0.77 fps) in a generally horizontal present method, using direction through the cross section of the first basin, aerators from the propeller shown in Fig. 1 and the Measured speeds from Fig. 3B type oxygen injection rates of more than 1361 kg lead to a mean linear speed of 65 (31b) oxygen per 745.54 watt (1 hp) hour or 0.177 ms / sec (0.58 fps) in a generally horizontal 1.826 ρ per watt hour can be achieved. Direction through a cross section of the second basin. While certain conventional aerators have the Fa-Diesse calculated mean pool velocities of injecting oxygen at the above

Claiming rate or speed is on this side no known ventilation system that injects oxygen and induces flow velocity combined in accordance with the method of the invention.

The F i g. 2A and 2B show one shape of an overall flow pattern according to the method of the present invention. That shown in these figures Overall flow pattern contains a closed overall flow pattern denoted by flow vectors 40, that in a closed overall flow pattern denoted by flow vectors 38 Fig. 5 shows an alternative overall flow pattern of water using two sets of aerators 10, a pair of closed ones Form overall flow patterns or paths which lie side by side or are adjacent to one another. The adjacent closed flow paths are denoted by horizontal flow vectors 44.

F i g. 6 shows a system of a total flow pattern corresponding to that from FIGS. 2A and 2B are similar here is an outer closed overall current path through horizontal Flow vectors 50 denote an inner closed total flow path is through horizontal Flow vectors 52 denoted The external flow denoted by the flow vectors 50 is generated by an outer set of aerators 10, while the inner flow path is generated by two aerators 10 is generated. One or more aerators of which in Fig. 6, two shown and designated by the reference numeral 54 are out of alignment with the inner flow path and are directed towards the center of the same. The aerators 54, which are not are aligned with the closed overall flow path, are aligned with the center of the flow path to create a water undercurrent path and the formation of empty flow areas in the center of the pelvis. The undercurrent path is denoted by horizontal flow vectors 56.

FIG. 7 shows a FIG. 6 similar variation of the aerator orientation, only a single set of aerators 10 being used to clear one through horizontal flow vectors 58 designated closed overall current path to form. A number of aerators 60 in Fig. 7 is not aligned with the closed overall flow in order to form an undercurrent path denoted by horizontal flow vectors 62, so that the creation of an empty flow path in the center of the basin is avoided. According to illustration If four aerators 60 are not aligned, any other number of cases can be used in be arranged in this way.

3 sheets of drawings ss

60

65

Claims (2)

1 2 Before venting the surface with the help of a waste water patent claims: PropeUer aerators immersed in a sewage basin through ventilation, which is largely from below the waste water 1. Device for aerating and circulating water surface takes place, replaces the propeller aerator Wastewater, consisting of several in one bath, 5 are aligned in such a way that all of the wastewater located in a treatment basin at an angle to the sewage basin is fed into one more arranged propeller aerators, whose propeller or less uniform circulation flow for mixing the sucked-in air with the settling, there is an intensive and uniform V " Propeller- io oxygen. In addition, there is also an air-acid aerator (10) aligned so that they supply substance through the surface of the sewage, The invention is explained below with reference to the drawing at least one circulation flow in detail, for example, specifically form action pool. shows 2. Apparatus according to claim 1, characterized in that Fig. 1 shows a side view of a single propeller that the propeller aerator (10) under an aerator, Angle of inclination between 12 and 25 degrees to the starting point. 2A is a plan view of a schematically indicated water level (12) are aligned. tete treatment basin, in which several propeller aerators are arranged, which 20 lungs basins in total into one ■ move the circulation flow, F i g. Figure 2B is a top view similar to Figure 2B. 2A one The invention relates to a device for ventilating modified treatment basins and circulating wastewater, consisting of several FIGS. 3A -sin diagram, from which the flow rate in a treatment basin at an angle to the wastewater speed at various points of the wastewater level arranged propeller aerators, the samples of which from FIG. 2A, peller for mixing the sucked-in air with FIG. 3B is a diagram similar to that in FIG. 3A for wastewater is completely submerged therein. Waste water basin from FIG. 2 B, In a known device of this type (FR-F i g. 4 a schematic representation of individual hori- OS 22 60 535) suck in the zontally circulating flow patterns at an angle of about 30, which are 45 ° to the sewage level in the treatment cells arranged side by side or one behind the other basin immersed propeller aerator the entire propeller aerator is generated, air used for ventilation through the water level in FIG. 5 is a plan view of another wastewater basin the treatment basin, whereby the effect of the ken with a different arrangement of the propeller aerator, single propeller aerator on moving the ab- 35 F i g. 6 is a plan view of a sewage basin, where- water is limited in its immediate vicinity, in the case of flow paths with a deviating arrangement of the so that interactions between the individual propeller aerators are drawn , and water streams generated by aerators only accidentally F i g. 7 a further plan view of a waste water basin and are not uniform. Accordingly, the ken, with a total circulation flow attached. atmospheric oxygen 40 to be mixed with the wastewater indicates and the propeller aerators are arranged in such a way that not only supplied unevenly, but also in such a way that there is also a lower flow, uniformly mixed with the sewage. In Fig. 1, a propeller-type aerator 10 is for The invention is based on the object of supplying a use in the method according to the invention. the illustrated ren loading in a treatment tank for aeration of the aerator 10 is, as shown sensitive wastewater used atmospheric oxygen with its lower end below the sewer equalize. gels 12 arranged. The aerator 10 has an exterior According to the invention, this object is achieved with a pre- tubular housing 14 and a rotatably supported therein. direction of the aforementioned genus with the genes inner tube 16. This extends in the Features of the characterizing part of the patent tubular housing 14 up to a level above Proverb 1 solved. An advantageous embodiment of the 50 of the sewage level 12 and is with one in one Invention is the subject of claim 2. Motor housing 18 carried motor in terms of drive. Since, according to the invention, the propeller aerator so couples the inner tube 16 has at least one hole are aligned that the individual generated by them its upper end above the sewage level 12, Flows in their entirety at least one circulation in order to allow air into the interior of the tube 16. That Formation flow in the treatment basin, 55 inner tube 16 extends over the lower end of the from the propeller ventilators the entire in the tubular housing 14 outwards and outwards Waste water in motion in the lungs basin has a propeller 20 attached to it. A diffusion so that a uniform mixing of the attached pipe 22 is also attached to the inner pipe 16 sucked air oxygen with the sewage and has a hollow inside that with the hollow inside will. Since the propeller aerator is preferably in flow connection under ei- ω of the inner tube 16, An angle of inclination between 12 and 25 degrees and in front when the inner tube 16 is rotated by the motor is preferably aligned 22 degrees to the sewage level, the propeller 20 is also rotated they also have a good depth effect, which itself creates a directed, turbulent flow if they are not too deep in the sewage basin, the containment field in the sewage. The stream slrom- are immersed, so that the circulation created by them 65 from the zone created by the propeller of reduced pressure If the sewage does not flow horizontally, it also causes air to be drawn through the hollow tube 16 which also moves in the vertical direction. or is sucked down and through an open Through the present invention, the hitherto ObIi- end of the diffusion tube 22 is as air bubbles 24 in the