DE102012016998B3 - Mixing device used for treatment of sewage, has aggregate supply portion that is provided at end of pipe section chamber and is equipped with mixing chamber for mixing of aggregate containing water and flocculants - Google Patents

Abstract

The mixing device (2) has an inlet (4), an outlet (6) and an aggregate supply portion (8) and a shaft (10). A stirring blade (12) is coupled with the shaft. The inlet and outlet are connected through a pipe section (14). The pipe section is provided with a chamber (16) in which the stirring blade is arranged and the aggregate supply portion is provided at the end. A mixing chamber (20) of the aggregate supply portion is equipped for mixing of an aggregate containing water and flocculants.

Description

The invention relates to a mixing device, comprising at least an inlet, an outlet and an additive supply and a shaft attached to a stirring blade, wherein the inlet and the outlet connect a pipe section and the pipe section has a chamber in which the stirring blade is arranged and in which Aggregate supply ends, wherein the additive supply has a chamber.

In the mechanical dewatering of sewage sludge mixers, the additions of z. B. flocculants, used. Such a mixer is from the DE 197 19 638 C2 known, wherein the aggregate guide extends in sections through the interior of the shaft and supplied additives such. B. flocculants from side slits on the shaft can escape before they are mixed in the chamber by the rotating stirring blade in the mud stream. However, this mixer has a complicated structure.

For the treatment of waste water as well as for the dewatering of sewage sludge polymeric flocculants (FHM) are used. These flocculants are z. B. from long-chain synthetic and / or organic polymers. When dissolved in water, these polymers form many positively and negatively charged particles. Therefore, the polymers are called polyelectrolytes. If so-called cationic polyelectrolytes are used, the negatively charged dirt particles to be removed from the wastewater can be flocculated. To be able to dewater sewage sludge by machine, a conditioning must be carried out in advance. This is done by means of the polyelectrolytes as flocculation aids for the separation of the suspended solids.

Commercially available flocculants differ in their chemical composition (charge type, charge content and charge distribution) and steric structure (molecular weight, molecular weight distribution and gel ball volumes). Polymers in emulsion form, with 30-50% active substance proportions, emulsified in carrier oils in so-called dissolving stations, are prepared to a 0.01-0.5% working solution prior to their use as flocculation aids.

These release stations are so-called two- or multi-chamber systems that operate in batch mode. In this case, a certain amount of polymer emulsion (30-50%) is added to a certain amount of water in an appropriate ratio in order to obtain the desired dilution (0.04-0.5%). The tangled molecular fibers of the polymer emulsions can now stretch in the water volume. This is done with the aid of a mixing device (stirrer), and is complete when the same viscosity is present in all areas of the chamber or the neck tank, d. H. a perfect mixing (even distribution) of the emulsion in the dilution water was achieved. The time required for this is generally also called the maturation time. It depends on the chamber or container size, active substance proportions of the emulsion, the desired dilution and, lastly, the registered mixing energy.

The disadvantages of these Lösestationen are the large space requirement, possible bacterial infestation and inflexible and slow change to other feedstocks and drug concentrations. Furthermore, the hold time of the finished flocculant use solution is limited. Unused solutions work after just a few hours of downtime, greatly reducing the effect of the effects, and even after 1 to 2 days at most, they are almost completely uneffective. For the plant operators, this means increased flocculant consumption and additional disposal costs for the effective flocculant use solution.

The well-known mixer from the DE 197 19 638 C2 can only interfere with flocculants in sludge that has been treated in previously mentioned dissolution stations.

From the DE 20 2006 017 563 U1 a mixer is known which comprises an inlet, an outlet and an additive feed and a shaft attached to a stirring blade, wherein the inlet and the outlet connects a pipe section and the pipe section has a chamber in which the stirring blade is arranged and in which the additive supply ends, wherein the additive supply has a further chamber for buffering the supply amount.

From the DE 10 2004 055 072 A1 For example, there is known a device for adding a polymer to a fluid which comprises a mixing device for mixing a fluid flocculant-air mixture.

It is therefore an object of the invention to remedy this situation.

The object is achieved by a mixing device having the features of patent claim 1.

According to the invention, the further chamber has a mixing chamber for mixing an additive containing water and flocculants. Thus, the aggregate is timely, namely, the flocculant utility solution. Therefore, the loss of efficiency is minimized by downtime of the flocculant utility solution and there is no disposal costs for ineffective flocculant use solution more.

In a preferred embodiment it is provided that at least one rotatably mounted mixing star is arranged in the mixing chamber. This improves the mixing of water and the flocculants to provide a flocculant utility solution with optimum efficiency. At the same time, the maturation time is shortened and a highly effective flocculation aid is produced.

In a preferred embodiment, it is provided that the mixing star has at least one mixing arm, which has a profile which is formed symmetrically. The profile is formed symmetrically to a longitudinal axis of the profile. The longitudinal axis may extend in the flow direction of the flocculant use solution or in the direction of the shaft to which the agitating blade is attached. This makes it possible to operate the mixing star in both directions. This is important because when operating in only one always the same direction of rotation, the fibers contained in the sewage sludge, can wrap around the mixing paddle, and thus leads to a malfunction, or a poor mixing of the flocculant takes place. By changing at certain intervals the direction of rotation this is avoided.

In a preferred embodiment it is provided that at least one further rotatably mounted mixing star is arranged in the mixing chamber. As a result, the maturation time is shortened again and the throughput can be increased.

In a preferred embodiment, it is provided that the further mixing star has at least one mixing arm which has a profile which is symmetrical. Again, the profile is formed symmetrically to a longitudinal axis of the profile. The longitudinal axis may extend in the flow direction of the flocculant use solution or in the direction of the shaft to which the agitating blade is attached. Thus, as already described, malfunctions or poor mixing of the flocculant can be avoided.

In a preferred embodiment, it is provided that the profile of the first mixing star and the profile of the further mixing star are arranged opposite to each other. The two profiles are thus arranged anti-parallel to each other in the flow direction of the flocculant auxiliary use solution or in the direction of the shaft to which the stirring blade is attached. As a result, water and flocculants can be fed into the mixing chamber in an intermediate space between the two mixing stars and then pass through one of the mixing stars in two oppositely directed partial flows. Thus, the space requirement for the mixing chamber can be kept small.

In a preferred embodiment it is provided that the at least one mixing star is fastened to the shaft. In addition, the other mixing star can be attached to the shaft. As a result, a single drive can be used both for the stirring blade and for the one or both mixing stars. Thus, in operation, the stirring blade and the one or both mixing stars rotate at the same speed. But it can also be provided a gear to operate the agitator blade on one side and the one or both mixing stars with different speeds. The drive can be any suitable motor drive, possibly used together with a gearbox. Preferably, however, it is provided that the shaft is connected to an electric motor, such as. B. a three-phase motor.

In a preferred embodiment it is provided that at least one flow calming sheet is arranged between the chamber and the outlet. The flow stabilization plate serves to calm the flow. It reduces the rotational component introduced by the stirring blade rotating in the chamber. Thus, a uniform flow of material is provided.

In a preferred embodiment it is provided that the aggregate guide has a channel which extends substantially parallel to the shaft. Thus, a much simpler structure without a hollow shaft is possible. Furthermore, better mixing results are achieved by a more uniform supply of aggregates.

In a preferred embodiment, it is provided that the shaft is arranged in sections in the channel, so that channel and shaft are arranged concentrically with each other. Thus, a uniform supply of aggregates along the circumference of the stirring blade is ensured and at the same time a simple and low-maintenance construction possible.

The invention will now be explained with reference to a drawing. It shows the only figure:

1 a section through a schematic representation of an embodiment of a mixing device according to the invention,

2 a section along the line AA the 1 .

3 a top view of a mixing star,

4 a detail of 4 and

5 a section along the line BB of 3 , and

6 a section through a schematic representation of another embodiment of a mixing device according to the invention.

Is shown in 1 an inventive embodiment of a mixing device 2 ,

The mixing device 2 has an inlet 4 and an outlet 6 on, the two a flange (not shown) for connection to a pipeline network, for example, a sewage treatment plant (not shown). The inlet 4 and the outlet 6 are through a pipe section 14 interconnected, flows through the sewage sludge in operation, to be mixed in the example. Flocculation aid.

For this purpose, the pipe section 14 a chamber 16 in which a stirring blade is rotatable on a shaft 10 is arranged, the shaft 10 directly with a drive, z. B. an electric motor (not shown) is connected. In the present embodiment, the pipe section 14 a 90 ° deflection on.

For the supply of z. B. flocculants is an additive feed 8th provided in the chamber 16 ends. In this case, the surcharge feeder 8th a channel 18 up in the chamber 16 ends. The channel 18 is annular, wherein the shaft 10 in sections in the canal 18 is arranged so that wave 10 and channel 18 are arranged concentrically with each other.

The channel 18 ends in its other extension direction in a mixing chamber 20 , In the mixing chamber 20 are on the wave 10 in the present embodiment, two mixing stars 22 . 24 rotatably mounted, so that in operation with driven shaft 10 both the stirring blade 12 as well as the two mixed stars 22 . 24 turn at the same speed. In the mixing chamber 20 opens a supply line 34 , In the present embodiment, the supply line extends 34 radially inwardly directed with respect to the axis of rotation of the shaft 10 to a gap 38 between the two mixed stars 22 . 24 in the mixing chamber 20 , In other words, the two are mixed stars 22 . 24 on the wave 10 in the direction of displacement of the shaft 10 spaced apart from each other.

In the flow direction between the stirring blade 12 and the outlet 6 In the present exemplary embodiment, four flow-calming sheets are provided 34 arranged.

2 shows that in the present embodiment, the four flow calming plates 34 evenly spaced on the inner circumference 40 of the pipe section 14 are arranged. The four flow calming sheets 34 cause in operation the Rotationskomponete, by the rotating blade 12 in the stream in the pipe section 14 is introduced, is eliminated, so that a calm flow of material is provided.

The 3 and 4 show that in the present embodiment, the two mixed stars 22 . 24 four mixing arms each 26 . 28 exhibit. The four mixed stars 26 . 28 are arranged evenly spaced in the circumferential direction. Each of the mixing arms 26 . 28 has a profile in the present embodiment 30 . 32 which is symmetrical. In the present embodiment, the profiles 30 . 32 symmetrical to the direction of extension of the shaft 10 (please refer 1 ). Furthermore, in the present embodiment, the two mixing stars 22 . 24 so on the wave 10 arranged the profiles 30 . 32 the respective mixed stars 22 . 24 are aligned anti-parallel to each other. Thus, the tips of the formed in the present embodiment as an isosceles triangles profiles 30 . 32 to each other (see 1 ).

5 shows that the profiles 30 . 32 in the present embodiment in cross section have the shape of an isosceles triangle.

6 shows a further embodiment of a mixing device 2 , It corresponds to the in 1 shown embodiment except for the difference that the pipe section 14 in this embodiment has no 90 ° deflection and free of Strömungsberuhigungsblechen 34 is.

In operation, in both embodiments, the mixing device flows 2 a stream, z. As sewage sludge, through the inlet 4 in the chamber 16 , At the same time flows through the supply line 34 Water and flocculants in the space 38 the mixing chamber 20 , These streams can be generated by pumps (not shown). By the effect of the two mixed stars 22 . 24 with their mixed arms 26 . 28 that are due to the driven shaft 10 Turning in operation, is in the mixing chamber 20 mixing the water and flocculant so as to provide a flocculant use solution.

The flocculant use solution then flows out of the mixing chamber 20 through the channel 18 in the chamber 16 , where they are affected by the stirring action of the stirring blade which also rotates during operation 12 with the stream, z. As sewage sludge is mixed. This mixture then leaves the mixing device 2 through the outlet 6 ,

To prevent clogging on the mixing paddle by containing sewage sludge pulps, a reversal of the direction of rotation 10 done to prevent or dissolve this. The symmetrical profiles 30 . 32 set in both directions equal optimal efficiency of the mixing stars 22 . 24 for sure.

Claims (10)

Mixing device ( 2 ), at least comprising an inlet ( 4 ), an outlet ( 6 ) and an additive feed ( 8th ) as well as one on a wave ( 10 ) attached stirring blade ( 12 ), whereby the inlet ( 4 ) and the outlet ( 6 ) a pipe section ( 14 ) and the pipe section ( 14 ) a chamber ( 16 ), in which the stirring blade ( 12 ) and in which the additive feed ( 8th ), the addition of aggregate ( 8th ) another chamber ( 20 ), characterized in that the further chamber ( 20 ) a mixing chamber ( 20 ) for mixing an aggregate containing water and flocculants. Mixing device ( 2 ) according to claim 1, characterized in that in the mixing chamber ( 20 ) at least one rotatably mounted mixing star ( 22 ) is arranged. Mixing device ( 2 ) according to claim 2, characterized in that the mixing star ( 22 ) at least one mixing arm ( 26 ), which has a profile ( 30 ), which is formed symmetrically. Mixing device ( 2 ) according to claim 2 or 3, characterized in that at least one further rotatably mounted mixing star ( 24 ) in the mixing chamber ( 16 ) is arranged. Mixing device ( 2 ) according to claim 4, characterized in that the further mixing star ( 24 ) at least one mixing arm ( 28 ), which has a profile ( 32 ), which is formed symmetrically. Mixing device ( 2 ) according to claim 5, characterized in that the profile ( 30 ) of the first mixed star ( 22 ) and the profile ( 32 ) of the further mixed star ( 24 ) are arranged opposite to each other. Mixing device ( 2 ) according to one of claims 2 to 6, characterized in that the at least one mixing star ( 22 ) on the shaft ( 10 ) is attached. Mixing device ( 2 ) according to one of claims 1 to 7, characterized in that between the chamber ( 16 ) and the outlet ( 6 ) at least one flow stabilization plate ( 34 ) is arranged. Mixing device ( 2 ) according to one of claims 1 to 8, characterized in that the additive supply ( 8th ) one the chamber ( 16 ) and the mixing chamber ( 20 ) connecting channel ( 18 ) substantially parallel to the shaft (FIG. 10 ). Mixing device ( 2 ) according to claim 9, characterized in that the shaft ( 10 ) in sections in the channel ( 18 ) is arranged.

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