EP0196575B1 - Device for mixing at least one flow medium - Google Patents

Abstract

The mixing apparatus has a plurality of pump impellers having one common axis and extending parallel to each other. Immediately adjacent pump impellers have opposite directions of rotation. The blading of the pump impellers is such that the currents of the mediums exiting the pump impellers have an as large as possible peripheral component. The medium currents exiting the adjacent pump impellers and having opposite senses of rotation are guided together and generate at the mutual point of contact an extremely high turbulence because the peripheral components of the exiting rotating currents of the mediums are directed oppositely to each other and eliminate each other practically immediately.

Description

The invention relates to a device for mixing at least one flow medium, wherein at least two partial flows of the flow medium are brought together to produce a very strongly turbulent flow.

Such a device is known from US Pat. No. 3,147,957 which has at least two pump impellers for the partial flows which are parallel and coaxial to one another, adjacent pump impellers being opposed, each pump impeller being assigned one of the partial flows. In this known device, the mixing of the flow media or media takes place within the device. When mixing in this known device, the mechanical shear action acts on the medium. The impellers are provided with grooves or ribs and the impellers are made of hard metal (carborundum) in order to exert the greatest possible shear effects on, for example, the liquids to be mixed. The effect of such a known device with two counter-rotating impellers is such that only the relative speed due to the two medium disks of opposite direction of rotation changes. The same effect can be achieved with a device with only one impeller if the impeller is rotated at double speed. In the known device, the impellers are subject to considerable wear (erosion, corrosion, cavitation) and, despite expensive manufacture, have a service life that one would like to increase.

The aim is to create a device with which the aforementioned disadvantages can be avoided so that great turbulence can be achieved in an economical manner.

The inventive design of the device results from the characterizing part of patent claim 1.

A different mixing method is thus used than in the known device mentioned. In the device according to the invention, the pump impellers can be manufactured much cheaper since they are no longer subject to the abrasions mentioned. The shear effect on the media or media no longer has to be acted upon, in any case no special precautions have to be taken to achieve this. According to the invention, the pump impellers are provided with forward-curved blades, so that they thereby become pure centrifugal impellers, which only have the task of converting the mechanical energy into hydraulic energy with the highest possible efficiency. According to the invention, the two partial flows are only mixed outside the pump impellers in that large cross flows (transverse to the two flowing medium disks) and consequently large turbulences occur in a small ring outside the device. These aforementioned cross flows act as turbulence enhancers (see also Lueger, Lexicon der Technik, fourth edition, Vol. 1 and 14, pages 587 and 589 and Pages 521, 522). The above-mentioned cross flows take place in the forward curved blades of the two pump impellers at a tangential speed, which is the most important speed component for the best possible mixing process. The radial speed determines, for a given geometry, the delivery rate of each pump impeller and is irrelevant for the mixing process, since the radial components of both pump impellers have the same direction and therefore do not contribute to increasing the turbulence. The conditions for the tangential speeds of both pump impellers, which are opposite, are completely different. The very high mixing effect is achieved by counteracting two cross flows with the high tangential velocity. The two pump impellers with forward curved blades and opposite direction of rotation are necessary for this. In the known device of US-A-3 147 957 there are straight pump blades and therefore the tangential speed of the medium emerging from each pump impeller cannot have the same high value (at a given speed) since the tangential speed of the emerging medium is only of the same size like the peripheral speed of the pump impeller. In contrast, in the device according to the invention, the two medium disks meet at their tangential speeds outside the device, so that the large transverse flows form, which result in very strong turbulence, which result in the at least one flow medium being mixed as intensively as possible.

• Fig. 1 zwei Pumpenlaufräder mit Auftreffpunkt und Flüssigkeitsgebiet mit grosser Turbulenz, in schematischer Darstellung,
• Fig. 2 die zwei Pumpenräder in konstruktiver Ausführung mit Innenwelle und Hohlwelle,
• Fig. 3 die Vorrichtung mit einem einzigen Antriebsmotor für die beiden Pumpenlaufräder, in schaubildlicher Darstellung,
• Fig. 4 die Vorrichtung mit zwei Antriebsmotoren für die beiden Pumpenlaufräder, und
• Fig. 5 eine weitere Ausführungsform der Vorrichtung mit zwei Antriebsmotoren, wobei die beiden Antriebswellen der beiden Laufräder auf voneinander abgewandten Seiten der Laufräder liegen.

Several exemplary embodiments of the subject matter of the invention are shown in the drawing. Show it:

• 1 shows two pump impellers with impact point and liquid area with high turbulence, in a schematic representation,
• 2 shows the two pump wheels in a design with an inner shaft and a hollow shaft,
• 3 shows the device with a single drive motor for the two pump impellers, in a diagram,
• Fig. 4 shows the device with two drive motors for the two pump impellers, and
• Fig. 5 shows a further embodiment of the device with two drive motors, wherein the two drive shafts of the two impellers are on opposite sides of the impellers.

In Fig. 1 there are two pump impellers 1 and 2 which are parallel and coaxial to each other. Both pump impellers 1 and 2 rotate about one and the same axis 3, but in the opposite direction of rotation. A first partial flow flows in the direction of the arrows 4 to the pump impeller 1, and a second partial flow flows in the direction of the arrows 5 to the second pump impeller 2. The first partial flow emerges as a rotating medium disk 6 from the pump impeller 1, and the second partial flow likewise emerges as a rotating medium disk 7 from the pump impeller 2. Both media discs 6 and 7 rotate in opposite directions. The two pump impellers 1 and 2 are expediently designed identically to one another and consequently, apart from the direction of rotation, have the same hydrodynamic characteristics. The two oppositely rotating liquid disks 6 and 7 touch each other at point 8, the two opposite circumferential components of the two liquid disks meeting each other and canceling each other practically immediately. The two liquid disks 6 and 7 have low radial speed components that determine the throughput of the pump impellers. Because of the sudden abolition of the mutually opposed tangential speed components, oscillating transverse movements of the liquid particles occur, which result in a very large amount of turbulence in the liquid region 9.

2, the two pump impellers 1 and 2 are shown somewhat more clearly. The pump impeller 1 is supported by a hollow shaft 10, and the pump impeller 2 is seated on an inner shaft 11 which is surrounded by the hollow shaft 10. The pump impeller 1 has a suction nozzle 12 for the partial flow 4, and the pump impeller 2 has a suction nozzle 13 for the partial flow 5. Both pump impellers 1 and 2 rotate in opposite directions about the axis 3.

In the example according to FIG. 3, the two pump impellers 1 and 2 are driven by a single drive motor 14 for rotating in opposite directions. As already mentioned, the pump impeller 1 is seated on the hollow shaft 10 and the pump impeller 2 is carried by the inner shaft 11. The drive motor 14 drives via a belt 15 on pinion 16 and 17. The pinion 17 is rotatably connected to the inner shaft 11. The pinion 16 is rotatably connected to a wheel 18 which meshes with a wheel 19 which is rotatably connected to the hollow shaft 10. In this way, the two shafts 10 and 11 are driven in opposite directions.

4, the two pump impellers 1 and 2 are driven in opposite directions by two drive motors 20 and 21. The motor 20 drives directly on the inner shaft 11 on which the pump impeller 2 is seated, and the motor 21 drives via a belt 22 on a pulley 23 which is connected to the hollow shaft 10 in a rotationally fixed manner. The two motors 20 and 21 have opposite directions of rotation.

In the example of the device according to FIG. 5, the pump impeller 1 is seated on a shaft 24, and the pump impeller 2 is seated on a shaft 25. The two coaxial drive shafts 24 and 25 of the two pump impellers 1 and 2 are thus on opposite sides of the pump impellers. A motor 26 is used to drive the shaft 24 and thus the pump impeller 1, and a motor 27 is used to drive the shaft 25 and thus the pump impeller 2. An intake port 28 leads to the pump impeller 1 and an intake port 29 leads to the pump impeller 2 merged flow media flow away via a nozzle 30.

In another embodiment, not shown, there could also be more than two pump impellers, with adjacent pump impellers always being in opposite directions. With three such pump impellers, three partial flows could then be achieved as liquid disks rotating alternately in different directions of rotation, which are brought together at one point. The pump impellers 1 and 2 are designed as centrifugal impellers with forward curved blades, so that the peripheral component of the speed of the emerging medium disks 6 and 7 is very strong has been increased. The circumferential component of the speed (tangential speed) of the two medium disks 6 and 7 can be set correspondingly large by appropriate speed of the pump impellers 1 and 2.

Claims (2)

1. Device for mixing at least one fluid, in which at least two partial currents (4, 5) of the fluid are brought together in order to generate a strongly turbulent current (9), comprising at least two parallel and coaxial pump impellers (1, 2) for the partial currents (4, 5), where neighbouring impellers rotate in opposite directions, each impeller being allocated to one partial current, characterized in that the impellers (1, 2) are centrifugal impellers with vanes that are curved forward so that the partial currents (4, 5) leaving the centrifugal impellers are shaped as rotary fluid disks (6, 7) in such a way that neighbouring fluid disks (6, 7) collide in a location (8) located outside the centrifugal impellers in order to generate a strongly turbulent current in a region (9) outside the centrifugal impellers.
2. Device according to claim 1, characterized in that the capacity of flow and the peripheral speed of the rotary fluid disk (6, 7) expelled by neighbouring pump impellers (1, 2) are the same.

Images