CH675368A5 - Injecting fine gas bubbles into liq. - via pores in boundary structure with compsn. to repel liq. - Google Patents

Abstract

From an adjacent intermediate storage chamber, gas is injected into a body of liq. (esp. air into a body of liq. sewage) through a porous sepn. layer. The layer is at least partly formed of organic or inorganic fibres, and is impregnated with hydrophobic material, e.g., paraffin, silicone or fluorcarbons. Similar materials may alternatively be applied to a barrier layer formed of porous foam or ceramic. Materials used depend on polarity of liq. medium. For injecting a large body of liq., e.g. the sewage in a settlement tank, the injection units may be spaced at intervals along an air or O2 supply line near the tank floor. ADVANTAGE - Gas is delivered in extremely fine bubbles, increasing exchange surface produced by total bubble surface area and prolonging the gas/liq. contact period.

Description

CH 675 368 A5

1

description

The present invention relates to a device for introducing a gas into a liquid medium, a method for introducing a gas 5 into a liquid medium using the device, and a ventilation element for introducing oxygen or air into waste water with a device.

When introducing gases into liquid media, in particular with the fine aeration of wastewater in the biological treatment process, there is the problem of introducing the gas into the liquid in the smallest possible bubbles in order to achieve the largest possible contact area on the one hand and on the other hand in order to achieve the longest possible dwell time of the gas bubbles in the liquid.

To solve this problem, the documents DE-A 2 942 604, DE-A 2 035 651 and AT-B 265 992 propose devices for the fine-bubble aerating of water which have a perforated film at the boundary layer between gas and liquid include. The passage openings for the gas into the liquid are designed in different ways in order to result in the smallest formation of bubbles when the gas passes through the liquid. Nevertheless, it turns out that the bubbles formed are still too large, so that there is still a need to form smaller bubbles.

Another device for introducing oxygen into waste water is proposed in DE-A 1 584 935, semi-per-meable walls being proposed in this device. The oxygen throughput here is based on pure diffusion through the wall into the waste water, so that the entry 35 does not take the form of a bubble. Since the passage of oxygen through this semi-permeable wall is very slow, such a device is not efficient enough for the introduction of oxygen into waste water. 40

It is therefore an object of the present invention to propose a device for introducing a gas, for example air or oxygen, into a liquid medium, such as for example waste water, so that the gas is introduced into the liquid in the form of very fine 45 bubbles in order to thereby create a to achieve the largest possible exchange area and a long dwell time of the bubbles in the liquid.

According to the invention, this is proposed by a device according to claim 1 and by a method according to claim 6.

To introduce a gas into a liquid medium, a porous surface structure is proposed at the boundary layer between gas and liquid, on which at least one coating is provided, which repels the liquid medium in accordance with the polarity.

For the introduction of oxygen into a liquid medium, consisting essentially of water, 60 it is further proposed according to the invention that a porous sheet is arranged at the boundary layer between a gas containing at least some oxygen, preferably air or pure oxygen, and the liquid, the 65

is at least partially waterproofed.

In a preferred device according to the invention, it is proposed that the fibrous sheet-like structure at the boundary layer is at least partially impregnated with water-repellent.

In a further embodiment variant, it is proposed that the fabric consist of a woven, knitted or non-woven fabric.

For the impregnation of the fabric, the use of a hydrophobizing agent is also proposed, which is preferably an emulsion which contains paraffins, fat-modified synthetic resins, silicones or fluorocarbons.

In a further embodiment variant according to the invention, it is proposed that the fabric be at least partially made of a porous foam or ceramic and at least partially impregnated with water-repellent.

For the introduction of oxygen into liquid media, consisting essentially of water, a method is proposed in which a gas, at least partially containing oxygen, is introduced into the liquid through a flat structure, the structure at least partially comprising a woven fabric, a knitted fabric or fleece, which is at least partially waterproofed impregnated.

The devices and methods proposed according to the invention are suitable for introducing oxygen or air into waste water.

Accordingly, a ventilation element is proposed for the introduction of oxygen or air into waste water, in which a device, preferably according to at least one of the claims, is proposed.

Furthermore, a ventilation element is proposed, which consists of at least one supply line for the gas, further of at least one chamber for receiving the gas, which is at least partially surrounded by the liquid, the separating surface between the gas chamber and liquid comprising a flat structure, at least partially consisting from a preferably water-repellent impregnated fibrous fabric, knitted fabric or fleece.

The above-mentioned devices or methods are not only particularly suitable for aeration of wastewater in the biological clarification process, but generally for the introduction of gases into liquids, especially of any gases into water-containing liquids and solutions. It is also conceivable to use the devices and methods according to the invention for the introduction of gases into polar solvents, coatings being provided at the interface which, depending on the polarity, have a repulsive effect on the solvents and correspondingly reduce the adhesion of the liquid to the surface.

Subsequently, a device according to the invention will now be explained on the basis of the example use for a ventilation element in the biological wastewater treatment stage with reference to figures.

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CH 675 368 A5

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Show it:

1 is a plate ventilation element in cross section using the device according to the invention,

2 shows the arrangement of a plate ventilation element on a collector tube,

3a shows the arrangement of several plate ventilation elements on a collector tube,

Fig. 3b shows the arrangement of angular ventilation elements on a collector tube.

In Fig. 1, a plate ventilation element is shown in section, which is suitable for introducing oxygen or air at the bottom of a wastewater clarifier.

Arranged on the peripheral periphery of a plate body 1 is a flange ring 2, held in place by fastening screws 3, and further two seals 4, in which the separating surface structure 8 according to the invention is clamped. In the center of the plate 1 there is a cover plate 5, held in place by fastening screws 6, and in turn two seals 7 which hold the sheet 8 in place. Arranged below the seals 7 is a distribution screw 9, in which the air supply line 11 is arranged, and which is sealed to the outside with seals 10. In this embodiment, the sheet-like structure 8 is designed as a circular membrane, below which the air chamber 12 is located, between the membrane and the plate body 1.

For example, polyesters, polyacrylics or glass fibers are suitable for producing the sheetlike structure according to the invention. The glass fiber can also serve to reinforce the fabric or the fleece. For preferred impregnation of the fabric or fleece, it is immersed, for example, in an impregnation liquor and then squeezed between rollers. The fleece or the fabric can also be coated with an impregnation compound. In the impregnation fleet, respectively. Impregnating compound can be, for example, an aqueous, self-crosslinking polyacrylic dispersion, which also i.a. fat-modified synthetic resins or a fluorocarbon dispersion is added. However, it is possible to use any fabrics, knitted fabrics, nonwovens and / or other porous materials, such as a foam or ceramic, to produce the sheet 8 according to the invention, the sheet being preferably at least partially water-repellent impregnated with a water repellent to meet the required requirements to fulfill.

According to FIG. 1, air now flows through the air supply line 11 into the distribution screw 9 and finally reaches the air chamber 12. Since the wastewater presses on the membrane 8 above the air chamber 12, the air must enter the air chamber with an excess pressure of, for example, one meter of water are pressed to lift the membrane from the plate body 1. This is held by the flange ring 2 on the periphery of the plate 1 and by the cover plate 5 in the center of the plate. Now the air flows through the membrane 8 into the wastewater, the smallest bubbles forming on the wastewater side. Because of the water-repellent coating of the membrane, the air does not have to overcome any adhesive forces of the water on the membrane, as a result of which the air lifts off from the membrane 8 in the form of a tiny bubble and reaches the waste water. The small bubbles formed in this way on the one hand result in the largest possible surface or Exchange area between the air and the waste water and on the other hand guarantee the longest possible dwell time of the air in the waste water.

In Fig. 2, a plate 1 is now arranged in relation to a collector tube 13, through which the air is fed centrally to plate 1. Again, the air flows from the collector 13 through the feed line 11 into the air chamber 12, which can be seen as a narrow gap between the plate 1 and the membrane 8.

3a finally shows three plate ventilation elements which are arranged along a collector tube 13. Collector pipes of this type can be arranged in a large number on the bottom of a clarification tank, as a result of which the wastewater is evenly aerated through the plate ventilation elements over the entire floor area.

3b shows an analogous arrangement of two-cornered ventilation elements 14.

Of course, the ventilation elements do not have to be round, but they can also be square, as shown in FIG. 3b, or even large.

The aeration elements according to the invention shown in FIGS. 1 to 3 are not only suitable for aeration of wastewater, but they can generally be used for the aeration of liquids, such as, for example, aqueous solutions. In this case, however, it must be ensured that both the type of fiber used and the water-repellent coating are selected in accordance with the chemicals contained in the solution, so that no chemical attack can take place.

Claims (1)

Claims 1. Device for introducing a gas into a liquid medium, characterized by a porous sheet (8) at the boundary layer between the gas and the liquid medium, at least one coating being provided on the boundary layer which repels in accordance with the polarity of the liquid medium this works. 2. Device according to claim 1 for the introduction of oxygen into a liquid medium, consisting essentially of water, characterized by the porous surface structure (8) at the boundary layer between an at least partially oxygen-containing gas and the liquid, which is at least partially impregnated water-repellent. 3. Device according to one of claims 1 or 2, characterized in that the fabric (8) at the boundary layer between gas and river 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 3rd 5 CH 675 368 A5 liquid consists at least partially of organic or inorganic fibers. 4. Device according to one of claims 2 or 3, characterized in that the fabric (8) is water-repellent impregnated with a hydrophobicizing agent which contains paraffins, fat-modified synthetic resins, silicones or fluorocarbons. 5. Device according to one of claims 1 to 4, characterized in that the fabric (8) is at least partially made of a porous foam or ceramic and at least partially impregnated with water repellency. 6. A method for introducing a gas into a liquid medium using the device according to one of claims 1 to 4, characterized in that the gas is introduced into the latter through the porous sheet (8) at the boundary layer between the gas and the liquid medium , at least one coating being provided on the boundary layer, which acts repulsively on the liquid medium in accordance with the polarity thereof. 7. The method according to claim 6, for oxygenation in liquid media, consisting essentially of water, characterized in that a gas, at least partially containing oxygen, is introduced through the fabric (8) into the liquid medium, the fabric at least partially is woven, knitted or non-woven fabric made of fibers, which is at least partially impregnated with water-repellent. 8. The method according to any one of claims 6 or 7, for introducing oxygen or air into waste water. 9. Aeration element for introducing oxygen or air into waste water with a device according to one of claims 1 to 5. 10. Ventilation element according to claim 9, consisting of - at least one feed line (11) for the gas, - At least one chamber (12) for receiving the gas, which is at least partially surrounded by the liquid, and - At least one separating surface between the gas chamber and liquid, which comprises a flat structure (8), at least partially consisting of a preferably water-repellent impregnated, fibrous fabric, knitted fabric or fleece. 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 4th