EP0204688B1 - Aerating device for liquids - Google Patents

Description

The invention relates to a ventilation device for liquids, consisting of a arranged in the bottom region of a container, air and liquid sucking rotor with a vertical axis of rotation and a stator surrounding the rotor, which has a closed ring of cross-sectional flow channels, each with an inlet opening for the Has liquid-air mixture, wherein the flow channels are inclined with respect to the radial direction in the direction of rotation of the rotor.

In known ventilation devices of this type (AT-B 269 038), the ventilation air drawn in axially via a central air line is conveyed radially outward into the stator with the liquid also drawn in axially by the rotor, with intimate mixing, which consists of two ring disks arranged at an axial distance from one another and out vertical guide walls inserted between these ring washers. The liquid-air mixture is expelled into the liquid to be aerated through the flow channels formed between the vertical guide walls, which are rectangular in cross section, so that uniform ventilation of the liquid can be achieved in a certain area around the stator. With increasing distance from the stator, however, the ventilation becomes weaker because the flow velocity of the ejected liquid-air mixture decreases rapidly radially outwards, and this already in the area of the flow channels. This means that the diameter of the container receiving the liquid to be aerated must not exceed a certain dimension in order to ensure uniform ventilation of the liquid over the entire container cross-section at a given rotor output.

In another known ventilation device (FR-B 2 444 494), a rotor, arranged within a coaxial housing and having a vertical axis of rotation, is arranged in the bottom region of the container, which rotor sucks liquid from the container with the aid of pump vanes and pumps it axially through the housing, through its inner wall Air is blown radially inward into the liquid flow. This downward flowing liquid-air mixture is pumped into a distribution clamp provided in connection with the cylindrical housing, approximately square in plan, from which two spaced-apart distribution channels extend on each circumferential side, which are inclined with respect to the radial direction in the direction of rotation of the rotor and on are angled again halfway outwards in the direction of inclination. Since the down-pumped liquid-air mixture builds up in the area of the distributor chamber and the flow resistance is additionally increased by angling the flow channels, large pressure losses can be expected in this known device. In addition, the air to be introduced into the liquid must be blown into the liquid flow sucked in by the rotor under a pressure exceeding the static liquid pressure, which not only requires the provision of compressed air, but also makes it difficult to evenly enter the air into the sucked-in liquid flow, so that despite a comparatively high energy input, no uniform ventilation of larger container cross-sections can be achieved.

The invention is therefore based on the object of improving a ventilation device of the type described at the outset with simple means such that, with a given rotor output, uniform ventilation can also be ensured over a larger container cross section.

The invention achieves the stated object in that the flow channels are separated from one another by wedge-shaped spaces, the apex of which lie between the immediately adjacent inlet openings, and in that the vertical boundary surfaces of each flow channel run parallel or converge or diverge at an angle of at most 7 _° .

Since, according to these measures, the vertical boundary surfaces of the individual flow channels run at least substantially parallel to one another, the exit velocity of the liquid-air mixture from the flow channels can be increased considerably compared to conventional stators with simple guide walls without having to increase the rotor power. The higher outlet velocity of the liquid-air mixture requires a correspondingly larger outlet width of the mixture, so that even ventilation of larger container cross sections can be ensured. This results in particularly advantageous construction ratios because the size and shape of the rotor determine the ejection volume of air and liquid and thus the desired ventilation rate, while the formation of the flow channels of the stator is responsible for the range of the liquid-air mixture expelled. The exit velocity of the liquid-air mixture ejected from the stator can be influenced by the shape of the flow channels. If the vertical boundary surfaces of the individual flow channels diverge towards the outer circumference of the stator, the exit velocity of the liquid-air mixture is correspondingly reduced compared to the entrance velocity into the stator. If the exit velocity is to be increased, the flow cross section of the flow channels towards the exit end must be reduced by the vertical boundary surfaces converging towards the outer circumference of the stator. However, the angle between the vertical boundary surfaces of the individual flow channels must not exceed 7 _° , unless increased eddy formation is to be accepted. In this context, it must be borne in mind that turbulent flows considerably limit the possible range of the liquid-air mixture expelled.

With increasing tank diameter, care must be taken to ensure that the distance between the flows of two adjacent flow channels in the Area of the peripheral wall of the container does not become too large, so that uniform ventilation of the container liquid can also be ensured in the region of the peripheral wall of the container. In order not to exceed a permissible maximum distance between the flows of adjacent channels, even with larger container diameters, a corresponding number of flow channels must therefore be provided.

The flow channels can be designed differently. For example, it is possible to form the flow channels by means of web plates which are provided between two annular disks arranged at an axial distance from one another. A particularly advantageous construction results, however, if the flow channels consist of U-profiles placed on an annular disc. This design not only offers advantageous manufacturing conditions with a comparatively low cost of materials, but also allows simple stator cleaning because the gusset areas between the individual U-profiles forming the flow channels are freely accessible.

• Fig. 1 eine erfindungsgemäße Belüftungsvorrichtung für Flüssigkeiten in einer zum Teil aufgerissenen, schematischen Seitenansicht,
• Fig. 2 den Stator dieser Belüftungsvorrichtung in einer zum Teil aufgerissenen Draufsicht,
• Fig. 3 einen Schnitt durch einen Strömungskanal nach der Linie 111-111 der Fig. 2 in einem größeren Maßstab,
• Fig. 4 eine der Fig. 3 entsprechende Darstellung einer Konstruktionsvariante eines Strömungskanales,
• Fig. 5 einen Horizontalschnitt durch einen Stator mit nach außen divergierenden Strömungskanälen und
• Fig. 6 eine der Fig. 5 entsprechende Darstellung eines Stators mit nach außen konvergierenden Strömungskanälen.

The subject matter of the invention is shown in the drawing, for example. Show it:

• 1 is a ventilation device according to the invention for liquids in a partially broken, schematic side view,
• 2 shows the stator of this ventilation device in a partially opened top view,
• 3 shows a section through a flow channel along the line 111-111 of FIG. 2 on a larger scale,
• 4 shows a representation of a construction variant of a flow channel corresponding to FIG. 3,
• Fig. 5 shows a horizontal section through a stator with outwardly diverging flow channels and
• FIG. 6 shows a representation of a stator corresponding to FIG. 5 with flow channels converging towards the outside.

According to the exemplary embodiment according to FIG. 2, the ventilation device shown, which is arranged directly above a container base 1, consists essentially of a rotor 2, which is driven by a motor 3, and a stator 4 surrounding the rotor 2. The vertical rotor shaft 5 passes through the Container bottom 1, on which the motor 3 is flanged. The air to be introduced into the liquid of the container is sucked in via an air line 6 and fed axially to the rotor 2, which at the same time draws liquid from the container through an annular opening 7 of the stator 4 and conveys it with the air into the stator, as indicated by the flow arrows is.

In the stator 4, the liquid-air mixture is received in flow channels 8, which according to FIGS. 1 to 3 are formed by vertical webs 9 which are inserted between two annular disks 10 and 11. The arrangement is such that adjacent webs 9 of flow channels 8 arranged directly next to one another diverge towards the outer circumference of the stator 4, so that the vertical boundary surfaces of the flow channels 8 run parallel to one another. This configuration results in an exit velocity of the flow from the flow channels 8 which corresponds approximately to the entry velocity of the liquid-air mixture conveyed into the stator 4 by the rotor 2, so that the flow continues over a large radius into the container due to the comparatively high exit velocity. This ensures even ventilation of containers of larger diameters if a corresponding number of flow channels ensures that the flows of adjacent flow channels do not diverge too much, especially against the region of the peripheral wall of the container.

As shown in FIG. 4, a particularly simple stator construction can be obtained in that the flow channels 8 are formed by U-profiles 12 which are placed on an annular disc 13. This design not only ensures simple manufacture, but also offers advantages in terms of stator cleaning because the gusset areas between adjacent flow channels are freely accessible.

In order to be able to determine the exit velocity of the liquid-air mixture from the stator for a given rotor power, which is required for the ventilation of a liquid container with a certain diameter, the vertical boundary surfaces of the individual flow channels 8 can deviate from their parallel course. If, for example, the webs 9 of the individual flow channels 8 are arranged diverging towards the outer circumference of the stator 4, the flow within the flow channels 8 is slowed down. The angle α between the vertical webs 9 must not exceed 7 _° , since otherwise with An increased eddy formation is to be expected, which greatly limits the range of the flow emerging from the flow channels 8.

If the flow speed in the area of the outer circumference of the stator 4 is to be increased compared to the entry speed, the webs 9 can converge towards the outside, as is indicated in FIG. 6. In this case too, the angle a between the vertical webs 9 of the individual flow channels must be limited to a maximum of 7 _° .

With the help of the aeration device shown, the special design of the stator enables liquid to be evenly ventilated over larger base areas, these aeration devices being particularly suitable for use in submerged vinegar fermentation, in yeast production or in wastewater treatment.

The invention is of course not limited to the illustrated embodiment of a ventilation device. For example, very differently constructed rotors can be used. B. is possible to suck liquid not only according to FIG. 1 on one side, but on both sides of the rotor. The Rotorkon Structure can also be carried out so that the air can be sucked in from below the rotor, and that the motor in the form of a submersible motor of known design is mounted in the container above the rotor. Of course, any gas other than air can be drawn in and distributed in any given liquid. Depending on the design of the rotor, the inclination of the flow channels 8 with respect to the radial direction is then to be determined, the number of flow channels being selected depending on the inclination of the flow channels and the container diameter. In addition, adjacent webs 9 of flow channels 8 arranged directly next to one another can be formed by a common intermediate body which has a wedge-shaped shape in plan, so that in turn the vertical boundary surfaces of each flow channel run at least substantially parallel.

Claims (2)

1. A device for aerating liquids comprising: a rotor (2) whose rotational axis is vertical and which is disposed near the bottom of a tank and which intakes air and liquid; and a stator (4) which extends around the rotor (2) and has a closed ring of right- angled cross-section flow ducts (8) each having an entry for the liquid-air mixture, the flow ducts (8) being inclined relatively to the radial direction in the direction of rotation of the rotor (2), characterised in that the flow ducts (8) are separated from one another by wedge-shaped gaps whose vertices are disposed between the immediately adjacent inlets, and the vertical boundary surfaces of each flow duct (8) either extend parallel to one another or converge or diverge at an angle of at most 7°.

2. A device according to claim 1, characterised in that the flow ducts are embodied by channel-section members (12) placed on an annular disc (13).

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