DE2922264C2 - Gassing device - Google Patents

Description

The present invention relates to a gassing device according to the preamble of claim 1.

Such a gassing device is described in DE-OS 26 46 517, being concentric to a there is an outer foam drop tube attached to a motor mount, the lower end of which merges into a horizontal umbrella. This serves to reduce the dwell time of the sucked in gas bubbles to enlarge and in this way to increase the gas input. In practice, however, it has been shown that larger bubbles can collect under the umbrella. which suddenly rise at its edge without the desired finely dispersed distribution would come about.

A comparable device is known from DE-PS 9 08 968 Here, air is sucked in through a suction pipe S \ n and brought into the liquid at its lower end with a motor-driven rotor so that it covers the rotor's conveyor vane disk body. Because the liquid rises directly at the edge of this narrow bubble shield, the gassing is not very effective.

According to FR-PS 10 13 342 is a bilateral bladed Disc body surrounded at the top and bottom by a pump housing slotted on the circumference, whose upper part is in one piece with the immersion tube and this continues coaxially with its lower part. The housing encloses the disc body at a relatively small distance, so that the liquid flow is hindered and a back pressure is inevitable, especially with higher toughness values. The device requires a relatively large drive power and still does not result in a high gas input, because that sucked gas together with the liquid is expelled at high speed and the gas just outside of the encapsulated reaction chamber in the form of rather coarse bubbles.

A similar device was disclosed in DE-PS 22 29 833. Here is the lower intake manifold Significantly shortened below the rotating disc body and the housing substantially in the radial direction more extensive, namely in the form of two parallel, approximately horizontal circular ring plates, but remains one increased flow resistance exist. This device therefore also has comparable disadvantages all relatively high friction losses in the narrow channel between the two circular ring plates.

Completely different flow and gas distribution ratios creates a device according to AT-PS 2 76 262 with a guide ring, its attachment in radial Distance to the gas-feeding immersion tube, a circulation with axial conveyance through the mixing propeller should effect. However, this way is fundamentally disadvantageous. The central opening is larger than that Rotor outside diameter and leaves an upward one. Liquid flow with coarse bubbles Air to. A mighty layer of air can form below the ring screen and slowly roll along it radially and the device floating on pontoons threatens to be lifted out of the water if the latter fails a dead load is weighted down.

The object of the invention is to provide a gassing device of the type mentioned in terms of gas input and performance ratios.

This is achieved by the features specified in the characterizing part of claim 1. The one from the bottom Immersion tube end from rising bubble screen causes namely under the promotion by the rotor an on average approximately horizontal outflow of the fumigated liquid. It spreads - in a vertical section b5 seen - in the form of a lying cone or funnel from selectable opening width. While one with a horizontal bubble screen in the manner of DE-OS 26 46 517 extended the residence time.

wanted to achieve carried gas bubbles, experiments have surprisingly inclined that deviating from Course of usual saturation curves of the gas entry with the device according to the invention thanks to the approximately horizontal outflow is fast at first and slower from a bend point a desired gas enrichment is often a little below the final saturation in practice, is often unnecessary all the time and energy required of the traditional slower gas input.

The measures of claim 2 have the advantageous consequence that the flow of the top of the dip tube is deflected horizontally along axially supplied liquid without loss increased radial pumping of the outflowing gas-liquid mixture with corresponding expansion the residence time of finely dispersed bubbles. The acute angle between the cover part and the bubble shield acts as a Tear-off edge that contributes significantly to the turbulence

Mention should be made in this context of a compressed air injection device according to DE-AS 22 59 016, which provides axial slots at the lower end of a pipe, above which an air bubble deflection pyramid is arranged so that at each slot a flat, after the sloping surface with a sharp edge is connected on the outside Air bubbles are broken up and distributed evenly. However, there is no mover for the liquid available, and also the application and mode of action of the known, exclusively polygonal surfaces having deflection pyramid differs from the inventive design of the bubble screen fundamental.

It was also found here that too great a radial expansion of the bubble shield is not an appropriate one Brings about improvement in fumigation; on the other hand, an umbrella that is too small is not effective enough. This results in the very favorable design rules of claims 3, 5 and 6.

The measures of claims 4 and 7 are important for the suction effect of the rotary immersion gasifier. A the rotor upstream gas guide body, as specified in DE-OS 28 23 515, can also in Within the scope of the present invention are used with advantage to at the lower end of a dip tube to get a defined annular space. This is expediently dimensioned so large that if there is still sufficient Suction negative pressure the liquid flow through the annular gap at high speed. At the sharp outlet edge, tear-off processes take place, which further promote the gas entry and flow dynamically The interaction with the bubble screen increases the energy efficiency even more.

The following is an embodiment of the invention explained with reference to the drawing. In it shows

F i g. 1 is an axial sectional view of a gas injection device and

2 shows an enlarged section of the lower one Part of Fig. 1.

A rotating submersible gas gasifier, designated as a whole by 10, is on a holding plate 12 above a liquid level 5 mounted. The holding plate 12 carries a support flange 14, preferably on rubber buffers hold a drive motor 16 which is enclosed by a housing 18 which is also fastened to the holding plate 12 and is covered by a roof 20 attached to the latter.

A flange socket 22 on the HaltCDlatte 12 is used for Attachment of a dip tube 26, which is concentric with the drive shaft 24 leading downwards from the motor 16 surrounds the lower end 28 of the dip tube 26 carries a rigidly attached bubble screen 30, the one has upper part 32 rising upwards towards the dip tube

The shaft 24 is provided at its lower end with a gas guide body 34 and a rotor 36, the Wheel disk 38 is occupied with conveyor blades 40 at least on the upper side, but preferably on both sides

In the example shown, the guide body 34 is designed as a cone, the smaller diameter of which corresponds to that corresponds to the shaft 24, while the lower, large diameter connects to the rotor 36 with its the lower limit of the guide body 34 protrudes through the lower immersion tube end 28, so that a portion of the Guide body of the mouth edge of the immersion tube end 28 with the smallest distance in the form of an annular gap facing

The design of this ping gap and the subsequent bubble screen 30 is important. Its underside forms an obtuse opening angle with the axis A of the drive shaft 24 (FIG. 2), which is preferably about 105 °, namely when the bubble screen 30 - as drawn and in terms of production engineering particularly favorable - is designed as a cone. The upper part 32 of the bubble screen 30 can also be conical, but sloping down from above. The perimeter of the bubble screen 30 may have a sharp edge.

While the underside of the bubble screen 30 to support an approximately horizontal outflow of the serves the gas-liquid mixture conveyed by the rotor 36 in the radial direction, its upper part 32 forms a deflection surface, which also deflects the liquid fed in from above into a horizontal position. The upper For this purpose, surface 32 of the bubble screen 30 can also extend concavely upward. It is the same possible to form the underside of the bubble shield 30 arched, preferably concave downwards, with

the opening angle tx at the lower immersion tube end 28 can be up to 135 °.

With the rotary immersion gasifier 10 there is a gas entry which deviates from the usual course Saturation curve takes place in such a way that the increase in gas input up to a kink is faster and from then on it takes place more slowly. The normal course of the curve following an exponential law is thus given by a steep and a flat straight line approximated. The arrangement is preferably made so that the inflection point - d. H. the desired gas enrichment, which in practice is often eKvas below the final saturation - is achieved in a very short time; the continuation of the slower gas entry (according to the from flatter straight lines emanating from the kink point) to the In many cases, saturation is no longer necessary.

The low-noise and low-odor ".-Working device 10 causes the introduced gas bubbles to remain for a long time with optimal use of the drive energy. As a result, there is a high turnover of oxygen during aeration, for example in sewage, liquid manure and sewage basins achieved. It can also be used to neutralize alkaline wastewater using flue gas, which are sucked in through the immersion pipe 26, for example, from the chimney of a boiler house

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For this purpose ί sheet of drawings

Claims (7)

Patent claims: 1. Device for gassing a liquid with a dip tube, with a disc having a rotor, which faces the lower end of the dip tube and has conveyor blades whose outer diameter is larger than the inside diameter of the dip tube, with a drive shaft arranged concentrically in the dip tube for the Rotor and with a radially projecting bubble shield directly adjoining the lower end of the immersion tube, the outer diameter of which considerably exceeds that of the rotor, characterized in that the bubble shield (30) is continuous on all sides from the lower end (28) of the immersion tube (26) increases, the bubble shield at least with its radially inner area and <ät axis (A) of the drive shaft (24) an obtuse angle! («), Preferably about 105 °, and that the transition from the dip tube to the bubble shield is designed as a sharp tear-off edge 2. Device according to claim 1, characterized in that that at the bubble screen (30) a continuously rising towards the dip tube (26) upwards Cover part (32) adjoins, which is connected to the immersion tube without interruption, wherein The bubble shield and cover part form an acute angle. 3. Device * according to claim 1 or 2, characterized characterized in that the ratio of the outer diameter of the bubble shield (£ /) to the rotor (36) im The range is from 1: 1.5 to 1: 4, preferably at about 1: 2.5. 4. Device according to at least one of claims ί to 3, characterized in that the lower At the end of the drive shaft (24) a gas guide element (34) arranged upstream of it is arranged on the rotor (26) is, which widens downwards and, delimiting a predetermined annular gap, with a sharp outlet edge near the lower immersion tube end (28) opens, preferably slightly below of the latter. 5. Apparatus according to claim 4, characterized in that the largest diameter of the gas guide body (34) has a ratio of approximately 3: 4 to the inside diameter of the immersion tube (26). 6. Apparatus according to claim 4 or 5, characterized in that the outer diameter of the Bubble screen (30) is around four times as large as the largest diameter of the gas guide body (34). 7. Device according to one of claims 4 to 6, characterized in that the dip tube end (28) runs in a shape that is at least the lower The end of the gas guide body (34) is geometrically similar or approximately the same contour.