EP3294442A1 - Device and method for generating gas bubbles in a liquid - Google Patents

Abstract

The invention relates to a device (1) for generating gas bubbles in a liquid in a container, comprising at least one rotatable hollow shaft (3) arranged horizontally in at least one container; at least one gassing disc (4) arranged vertically on the at least one hollow shaft; and at least one feed line (2) for supplying at least one compressed gas to the interior of the at least one hollow shaft (3), said compressed gas being brought into the feed line and hollow shaft directly, without a liquid carrier.

Description

 Apparatus and method for generating gas bubbles in a liquid

The present invention relates to a device for generating gas bubbles in a liquid according to claim 1, a method for generating gas bubbles in a liquid using such a device according to claim 13, a plant for purifying water comprising such a device according to claim 16 and a A process for purifying water using such a plant according to claim 17.

description

Gas bubbles in liquids are necessary for a number of different applications, such as for the purpose of dissolving gas in the liquid. An increasingly interesting and important application of gas bubbles in liquids is the purification of water and other liquids in a so-called flotation process. Flotation is a gravity separation process for the separation of solid-liquid or liquid-liquid systems. In this case, gas bubbles, for example from air, generated and introduced into the liquid phase, wherein in the liquid phase located hydrophobic particles, such as organic substances or biological waste products, attach to these also hydrophobic bubbles and caused by the gas bubbles caused buoyancy of the Ascend surface. On the surface of the liquid phase, these agglomerates accumulate to form a sludge layer which is easily mechanically separable.

The flotation effect is the stronger the higher the specific surface of the rising gases, to which the hydrophobic particles can accumulate from the water to be purified. Accordingly, the formation of microbubbles with

Diameters of 10 to 100 μηη in the form of a bubble swarm (also called "white water") desirable. One way of introducing gas in the form of smallest bubbles into the liquid to be purified is effected by means of the known DAF process (dissolved air flotation). In this case, a gas present in a liquid at elevated pressure in dissolved form is introduced into the liquid to be purified, and due to the pressure drop in the liquid to be purified, the gas escapes in the form of very small bubbles which have a diameter in the micrometer range. The DAF method enables very good separation of microalgae from other microorganisms, oils, colloids, and other organic and inorganic particles from highly loaded wastewater, but requires relatively high energy consumption due to the introduction of air into the liquid by means of a saturation column associated with high energy consumption. At high temperatures (greater than 30 ° C) and salt contents (greater than 30,000 ppm), the process is becoming increasingly inefficient or even ineffective.

Another possibility for introducing smallest gas bubbles into a liquid while avoiding the high energy consumption arising in the context of the DAF method is described, inter alia, in WO 2013/167 358 A1, in which the gas is introduced by direct injection of a gas via a gassing membrane into the takes place to be cleaned liquid. This eliminates the otherwise usual in the DAF process recycle stream and the saturation column, since the gas, for example, directly from a compressed air line or a gas cylinder can be removed.

WO 2008/013349 A1 uses ceramic disks for producing microbubbles for separating impurities in waste water, the ceramic disks having an average pore size of between 0.01 μm to 0.05 μm. However, such small pore sizes are in use, for example, of salt water or very heavily polluted water, e.g. muddy water, in no way practicable, since saline or muddy water has a higher density or viscosity than normal water and adds the small pores to the ceramic discs. The smaller the pore size, the more difficult it is to produce bubbles on submerged porous surfaces and the greater the energy expenditure required for this. The in the

WO 2008/013349 A1 described membrane and device is therefore economically viable for large-scale use in any way. Another approach for the generation of micro bubbles is described in EP 2 081 666 B1, wherein here the generation of the micro bubbles takes place by means of oscillation. In the context of the described method, a compressed gas flowing in a line is set in oscillation, without resulting in an oscillation of the gas line. The oscillation is effected here by a fluidic oscillator, wherein the oscillations produced are such that they have a gas reflux of 10 to 30% of a resulting bubble. The oscillations caused by the fluidic oscillator are at a frequency between 1 and 100 Hz, preferably between 5 and 50 Hz, preferably between 10 and 30 Hz, and the bubbles formed have a diameter between 0, 1 and 2 millimeters. However, with the device described in EP 2 081 666 B1, the generation of micro bubbles (less than 100 μm) is not possible for large-scale application.

The object of the following invention was therefore to provide a device and a method for generating gas bubbles in a liquid, which allow a cost-effective and practical large-scale use, in particular in the context of the purification of dirty water or salt water.

This object is achieved with a device having the features of claim 1 and by means of a method according to claim 13.

Accordingly, an apparatus for generating gas bubbles in a liquid, in particular in a salt-containing liquid and / or heavily contaminated liquid, is provided, which comprises at least one horizontally arranged in at least one container rotatable hollow shaft, at least one, preferably at least two, more preferably at least at least three or more gassing discs arranged vertically on the horizontal rotatable hollow shaft, and at least one supply line for at least one compressed gas in the interior of the at least one rotatable hollow shaft, wherein the compressed gas is introduced directly into the supply line and hollow shaft without liquid carrier.

According to the invention, the at least one hollow shaft comprises at least one first hollow shaft with a diameter d3a and a second hollow shaft with a diameter d3t>, where d3a <d3b, so that the first hollow shaft is arranged within the second hollow shaft. Accordingly, the hollow shaft consists of two (part) hollow shafts, which are interleaved or nested: a smaller diameter first (part) hollow shaft, which is arranged in a larger diameter, second (part) hollow shaft. The diameter of the inner and outer hollow shaft can be between 10 and 50 mm, for example at 10, 20 and / or 40 mm.

The compressed gas is preferably conducted into the interior of the first (smaller) hollow shaft. Since the at least one first rotatable (smaller) hollow shaft consists of a gas-permeable material (for example perforated material), the gas can enter from the interior of the first (smaller) hollow shaft into the interior of the second (larger) hollow shaft.

The gas permeability of the material of the first (smaller) hollow shaft can be effected by holes with a diameter of 1 to 5 mm, which are arranged or distributed at different positions. Also, the use of inserted into the material slots or a (stiff) network would be conceivable.

The first (smaller) hollow shaft and the second (larger) hollow shaft are preferably made of a metallic or a non-metallic material. Both hollow shafts can be in one-piece form.

The hollow shaft used in the present case can also be described as a type of hollow cylinder, wherein between the inner and outer lateral surface, a cavity or a hollow volume is provided, and wherein the inner circumferential surface is gas-permeable.

In the present case, an apparatus is provided for generating gas bubbles in a liquid, in particular microbubbles, which enables bubble generation by means of suitable gassing disks. The compressed gas is for this purpose introduced into the horizontally mounted rotatable hollow shaft (inner, smaller and outer, larger hollow shaft) and passed through the gassing, which consist for example of a ceramic membrane with a gas channel in the liquid. By using two nested hollow shafts a uniform and symmetrical pressure distribution within the larger hollow shaft is possible. Thereby the disks are symmetrically supplied with gas and it is achieved a uniform bubble production in the medium to be fumigated.

As will be explained later, the ceramic membrane has, for example, a pore size of two microns, which causes the formation of bubbles with a bubble size between 40 to 60 μηη. Due to the rotation of the hollow shaft and the ceramic disks mounted on the hollow shaft, shearing forces act on the gas bubbles emerging from the ceramic disks, which influence the size of the gas bubbles and the bubble swarm. The strength or size of the acting shear forces therefore has a direct influence on the effectiveness of blistering. The strength of the shear forces themselves is in turn influenced by the rotational speed of the hollow shaft, wherein the rotational speed of the hollow shaft can be up to 250 rpm.

The bubbles formed in the liquid in the form of a bubble swarm subsequently accumulate in the liquid particles of dirt (for example organic substances or biological substances) and rise in the form of a corresponding gas bubble agglomerate to the liquid surface. The solid layer subsequently formed on the liquid surface can then be mechanically separated. The specific combination of gas oscillation, direct gas injection in the supply line and hollow shaft and the vertical arrangement of the gassing on the horizontal hollow shaft enables the generation of micro bubbles in an energetic and thus cost-effective manner, making a large-scale industrial application of the device makes sense. In one embodiment of the present device are two horizontal rotatable

Hollow shafts offset parallel to each other. Each of the hollow shafts has in each case at least one gassing disc, preferably at least two, in particular preferably at least three or more gassing discs. Also, it is generally possible and conceivable that at least one hollow shaft not only 1 to 4 but also 10 to 100, preferably between 15 and 50, particularly preferably between 20 and 30 of

Gassing discs are arranged, wherein the number of ceramic discs is determined by the required amount of gas. The distance between the arranged on a hollow shaft ceramic discs is at least 2 cm. In the case of using a device having two hollow shafts arranged horizontally offset from each other in parallel, at least one gassing disc rotates on a first hollow shaft in the same direction to at least one gassing disc on the second hollow shaft arranged in parallel horizontal offset. Accordingly, the gassing discs engage one another offset. In this case results in a phase shift of 180 °. "Offset" in the sense of the present invention means that the hollow shafts are arranged laterally or spatially or horizontally offset from one another; that is to say the shaft holders or shaft bearings of the respective hollow shafts are preferably displaced relative to one another by a specific distance along a horizontal plane. The gassing, which are each arranged identically in a variant on the on each of the hollow shafts, thus do not touch due to the staggered arrangement of the hollow shafts, but rather engage offset into one another. In another variant of the device but also an offset arrangement of the individual gassing discs is conceivable and possible. In this case, the hollow shafts would each be arranged parallel to each other, that is, the shaft mounts are each parallel to each other, however, the gassing on the respective hollow shaft may not be provided in a fixed predetermined configuration, but rather on each hollow shaft at a different distance from the respective Gas access to be arranged in the hollow shaft. This distance can be dimensioned so that the gassing discs can interlock offset.

In a variant of the present device rotates the at least one hollow shaft with a rotational speed between 10 and 250 rpm, preferably between 100 and 200 rpm, more preferably between 150 and 180 rpm. In the case of using two parallel staggered hollow shafts, a lower rotation to Example between 50 and 100 rpm suffice. The rotational speed of the hollow shafts and thus also the rotational speed of the gassing as well as gas quantity and gas pressure can be changed during the operation of the device depending on the desired bubble formation, that is quantity and size of the bubbles, online (life).

In a further variant of the present device, the at least one compressed gas to be introduced is selected from a group consisting of air, carbon dioxide, nitrogen, ozone, methane or natural gas. Methane finds particular use in the removal of oil and gas from a liquid, such as in the case of purification a fracking fluid. Ozone, in turn, can be used to purify aquaculture water for its oxidative and antibacterial properties. The compressed gas is introduced as described above in the at least one supply line and consequently in the at least one hollow shaft directly without liquid carrier. Accordingly, a direct injection of the compressed gas takes place directly from a gas reservoir, such as a gas cylinder or a corresponding gas line. Accordingly, the gas does not require a liquid carrier, as is the case for example in the case of the DAF requirement, so that a recycle stream and a saturation column are eliminated and no compaction energy is required for achieving a high pressure level in the DAF recycle stream. Another advantage of the direct injection of a compressed gas without liquid carrier is that it enables a simple and low-energy generation of microbubbles.

The gas pressure of the gas introduced into the at least one hollow shaft is between 1 and 5 bar, preferably between 2 and 3 bar. In order to achieve this pressure level in the hollow shaft, the at least one compressed gas is introduced into the gas supply line at a pressure between 5 and 10 bar. The pressure curve within the hollow shaft is preferably constant.

In a further embodiment of the present device, the at least one gassing disc consists of a ceramic material with an average pore size between 0.05 μm and 10 μm, preferably 0.1 and 5 μm, particularly preferably between 2 and 3 μm. A pore size of 2 μηη is the most advantageous.

The average bubble diameter, the gas bubbles introduced into the liquid via the gassing disk or gassing membrane, may be between 10 μm to 200 μm, preferably between 20 μm to 100 μm, particularly preferably 30 to 80 μm, very particularly preferably 50 μm. Bubble production at the

Fumigation membrane or gassing can be influenced in particular via a suitable gas flow rate and pressure. The higher the pressure, the more and the bigger bubbles are created. The set volume flow plays in the present case only a minor role. The gassing disc has an outer diameter between 100 and 500 mm, preferably between 150 and 350 mm. Ceramic has proven to be a particularly suitable material for the gassing disks, in particular aluminum oxide 0Al2O3. However, other ceramic oxides and non-oxides such as silicon carbide or zirconium oxide can be used.

The ceramic discs can be stretched on the hollow shaft in at least one area (clamping area) and are simultaneously sealed by the voltage with seals made of any materials. The at least one clamping range is limited by two end pieces. The ceramic discs are preferably spaced apart by spacers (spacers) made of metallic or non-metallic materials and whose dimensions may vary. The present construction of hollow shafts, end pieces, spacers and ceramic discs is rotatable.

In a further variant of the present device, the at least one hollow shaft made of stainless steel, such as V2A or 4VA, duplex or super duplex material, or plastic. The overall diameter of the hollow shaft is between 10 and 50 mm.

As already indicated above, the at least one hollow shaft is arranged in each case two shaft holders with corresponding bearings. On the one side or the one end of the hollow shaft, the at least one supply line for the compressed gas is provided in the hollow shaft, while at the opposite end of the hollow shaft for the gas, a corresponding motor for rotating the hollow shaft is arranged and e.g. is connected via a drive shaft. Such motors for driving hollow shafts are known and can be varied depending on the size of the system can be selected.

In a further embodiment of the present device, at least one device for generating a pulsation of the compressed gas is provided in the at least one feed line. This pulsation generation apparatus may prefer pulsation of the compressed gas at a frequency between 5 and 15 Hz generate between 7 and 13 Hz, more preferably between 9 and 1 1 Hz. When using a pulsating (or ozsillating) gas to produce the gas bubbles in the present device, the energy requirement is reduced and the necessary gas pressure is reduced.

In a variant of the present device, the at least one device for pulsation generation is a fluidic oscillator, an automatic valve, for example in the form of a solenoid valve, and / or a positive displacement compressor, for example in the form of a reciprocating compressor. In general, it is also possible that the pulsation of the compressed gas in the supply line can also be caused in the form of a pulsating compressed air.

In a further embodiment of the present device, the pulsation generation device provides a gas reflux of <10 percent, preferably> 9 percent, or> 30 percent, preferably> 35 percent, during each pulsation.

As already mentioned above, a pulsation frequency, in particular oscillation frequency of the compressed gas between 9 and 11 Hz, is particularly preferred since at this frequency micro bubbles with an average bubble diameter of approximately 50 micrometers are produced. At an elevated frequency above 10 Hz, for example at 15 Hz, however, the bubble diameter is greater than at a lower frequency.

On the other hand, if no oscillation frequency is applied, only a bubble diameter having a size of 60 microns and above is generated.

The present apparatus is used in a method of producing gas bubbles in a liquid in a container by the steps of: introducing a compressed gas into at least one supply line, the compressed gas being introduced directly into the supply line without liquid carrier;

Introducing the compressed gas into at least one horizontally arranged rotating hollow shaft, in particular the first rotatable hollow shaft; and where the at least one hollow shaft is rotated at a rotational speed between 10 and 250 rpm, preferably between 100 and 200 rpm, more preferably between 150 and 180 rpm, and introducing the compressed gas into the fluid through at least one gassing disc arranged vertically on the horizontal rotating hollow shaft the gas bubbles.

With the present method, it is possible bubbles in the liquid having a bubble size between 1 μηη and 200 μηη, preferably between 20 μηη and 100 μηη, more preferably between 30 and 89 μηη, most preferably between 45 μηη and 50 μηη to produce.

In a preferred variant, the present device is used for generating gas bubbles in a plant for purifying a liquid, preferably water, in particular for purifying salt water or its pre-purification, of sludge-containing wastewater and other polluted liquids.

Such a system for purifying a liquid, such as water, comprises at least one container with a device for generating gas bubbles as described above and at least one container (flotation cell) for receiving the at least one gas bubbles mixed liquid, said container has at least one filtration unit for the separation of organic constituents contained in the liquid.

In a variant of the present arrangement, the container with the device for generating gas bubbles may be preceded by at least one flocculation unit for receiving the liquid to be cleaned and for receiving at least one flocculating agent for flocculating constituents contained in the liquid.

In a further variant of the present system, the at least one flocculation unit, the at least one device for producing gas bubbles and the at least one container (flotation cell) with the at least one filtration unit are arranged relative to one another such that they are in fluid communication with each other, such that the liquid to be purified mixed with the flocculating agent is transported from the flocculation unit into the device for producing gas bubbles and subsequently out of this device into the container (flotation cell) with the filtration unit.

The flocculation unit can either be designed as a separate unit separate from the other containers or be integrally connected to the other containers. The liquid to be purified, such as the water to be purified, is introduced into a suitable flocculating agent, such as Fe ³⁺ or Al ³⁺ salts, for example FeCU, and optionally mixed intensively with the liquid using a stirrer. The liquid added in the flocculation unit with the flocculating agent is then preferably transferred to the at least one container with the device for producing the gas bubbles in the form of a liquid stream, wherein the liquid stream in this container is mixed with gas bubbles introduced via the device for producing gas bubbles.

The resulting agglomerate of gas bubbles and flocculated organic constituents is then fed into the further vessel (flotation cell) with the at least one filtration unit, the gas bubble agglomerate and the flocculated organic constituents in the flotation cell rising to the surface of the liquid, accumulating there and mechanically be separated. The liquid freed from the majority of the organic components in this way is finally drawn off through the filtration unit arranged on the bottom surface of the flotation cell and fed to further treatment steps. Accordingly, in one embodiment of the present system, the at least one filtration unit is arranged in the flotation cell below the layer formed by the swollen, flocculated organic constituents. It is particularly preferred if the at least one filtration unit is arranged at the bottom of the flotation cell and is provided correspondingly immersed in the liquid region of the flotation cell.

The filtration unit has, in particular, a rectangular shape adapted to the container (flotation cell). The length of the filtration unit preferably corresponds to 0.5 to 0.8 times, more preferably 0.6 times the length of the flotation cell. The width of the filtration unit preferably corresponds to 0.6 to 0.9 times, particularly preferably 0.8 times the width of the flotation cell. Thus, the filtration unit does not extend completely over the entire width of the flotation cell, but rather has a small distance from the elongated sidewalls of the same. In height, the filtration unit is designed so that it corresponds to the height of the container (flotation cell) in a range between 0.1 to 0.9 times, preferably 0.6 to 0.7 times. Of course, other dimensions for the coming to use filtration unit are conceivable.

In a preferred embodiment, the at least one filtration unit is in the form of a ceramic filtration membrane, in particular in the form of a ceramic micro- or ultrafiltration membrane. Such ceramic filtration membranes have a high chemical resistance and a long service life. In addition, ceramic filtration membranes are more water-permeable and less prone to fouling as they have higher hydrophilicity than polymer membranes. Due to their mechanical stability, no pre-screening is required. A membrane module which has a mean pore size of from 20 nm to 500 nm, preferably from 100 nm to 300 nm, particularly preferably 200 nm, has proven to be particularly suitable. The preferred filtration membrane module may be formed from multiple plates, one or more tubes, or other geometric shapes. As a particularly suitable ceramic material, aluminum oxide has been found to be 0Al 2 O 3, but other ceramic oxides or non-oxides such as silicon carbide or zirconium oxide are also suitable for use in the filtration unit.

In a further preferred embodiment, the plant, here in particular the flotation cell, comprises a means for aerating the filtration unit about the at least one

Ventilation filtration unit in a suitable manner. For example, a suitable aeration means may be in the form of perforated tubes. The aeration means may be fed with air to apply large shear forces to the surface of the filtration unit to prevent or minimize fouling on the membrane surface. Other ways to prevent or reduce the fouling of

Filtration unit are the treatment with suitable chemical substances such as citric acid to prevent inorganic fouling or a suitable oxidizing agent, such as sodium hydrochloride to reduce the biological fouling. Accordingly, the system described can be used in a process for purifying a liquid, in particular for purifying water, for example for purifying or pre-purifying seawater. Such a method comprises the steps:

optionally introducing the liquid to be purified into at least one flocculation unit and adding at least one flocculating agent to the liquid to be purified for flocculating constituents in the liquid, such as organic constituents,

Transferring the liquid optionally added with the at least one flocculating agent into at least one downstream container with a device for producing gas bubbles and contacting the liquid optionally added with the flocculating agent with the gas bubbles introduced in this container to form a gas bubble agglomerate, in particular a flake Micro-gas bubble agglomerate,

Transferring the liquid mixed with the gas bubbles and the optional flocculating agent into a flotation cell, whereby the gas bubble agglomerate, which has risen to the surface of the flotation cell, is separated, and

Removing the liquid freed of the gas bubble agglomerate by the at least one filtration unit arranged in the flotation cell, and

- Feeding the withdrawn through the filtration unit liquid to further treatment steps.

The present method accordingly provides a hybrid process of gas bubble generation using vertically on a hollow shaft

Gassing discs, microflotation and membrane filtration in a singular device unit. The invention will be explained in more detail with reference to the figures of the drawings of an embodiment. Show it:

Figure 1A is a first schematic side view of an apparatus for

 Gas bubble generation in a liquid according to an embodiment,

Figure 1 B is a second schematic side view of an apparatus for

 Gas bubble generation in a liquid according to an embodiment,

Figure 2A is a schematic view of two mutually parallel offset

 Hollow shafts with multiple gassing according to a second embodiment;

Figure 2B is a schematic side view of rotating gassing, and

Figure 3 is a schematic side view of a plant for cleaning a liquid comprising a device for generating gas bubbles.

A general construction of a first embodiment of the device according to the invention for producing gas bubbles is shown in FIG. 1A.

The side view of Figure 1A comprises a device 1 with a supply line 2 for the supply of the compressed gas, a hollow shaft 3, through which the compressed gas is further introduced into the gassing 4.

In the embodiment shown in FIG. 1A, four circular gassing disks of a ceramic material are arranged on the hollow shaft. The ceramic discs are made of alumina, have an outer diameter of 152 mm and an inner diameter of 25.5 mm. The membrane surface is between 0.036 m ² and the pore size of the gassing discs is in a range of 2 μηη. The gas is introduced from the hollow shaft 3 in a cavity of the ceramic disc 4 and penetrates from the cavity interior through the pores of the ceramic material in the liquid to be purified, which is provided around and above the provided with the gassing discs hollow shaft, to form micro bubbles having a bubble size from about 45 to 50 μηι a. The gassing discs 4 are arranged on the hollow shaft by means of stainless steel or plastic fasteners. The distance between the gassing discs from each other can be chosen arbitrarily. At the gas supply line 2 opposite end of the hollow shaft 3, a suitable device for moving the hollow shaft is provided. This device may be provided in the form of a motor, which transmits the corresponding rotational movement via a plurality of gears on the hollow shaft. The embodiment shown in Figure 1 B illustrates the structure of the hollow shaft 3. This consists of two nested hollow shafts 3a, 3b: a smaller diameter hollow shaft 3a, which is arranged in a larger diameter hollow shaft 3b. By this principle, a very uniform and symmetrical pressure distribution within the larger diameter hollow shaft 3b is possible. Thus, the ceramic discs 4 are symmetrically supplied with gas and a uniform bubble production in the medium to be gassed is achieved. The shafts 3a, 3b can be made of metallic and non-metallic materials.

The ceramic discs 4 are stretched on the shaft, in at least one clamping range, and at the same time sealed via the tension with seals made of any materials. The at least one clamping range is limited by two end pieces 6.

As spacers between the ceramic discs 4 are intermediate pieces 5, which consist of metallic or non-metallic materials and their dimensions may vary. It is essential that the entire apparatus consists of hollow shafts

3a, b, end pieces 6, spacers 5 and ceramic discs 4 rotates.

The drive 7 for the rotating movement of the shaft can take place directly on the shaft, but can also be driven by different mechanical power deflections. For example: bevel gearbox, geared 90 ° gearbox. Thus, the drive 7 of the shaft can find its position not only in the medium to be aerated but also outside the medium to be aerated. The drive 7 can be provided via all known drive types (eg: electric / via hydraulic power / via air pressure). The shaft 3a, b is mounted at least two positions, different types of bearings can be used, eg: ball bearings, deep groove ball bearings, needle roller bearings, roller bearings. The gas entry 2 into the rotating shaft must take place via at least one seal. This can be positioned inside and outside the medium to be aerated. Drive 7 and gas introduction 2 into the shaft can be positioned anywhere on the shaft.

The illustration shown in Figure 2A shows two hollow shafts, each with four gassing discs, which are arranged offset from each other in parallel. The gassing discs on each of the hollow shafts move in the same direction to each other and engage each other due to the offset horizontal arrangement (Figure 2B). Such an arrangement of two parallel hollow shafts with the corresponding gassing discs makes it possible to generate a large number of microbubbles and thus a high surface area of gas bubbles, which is available to an accumulation of foreign substances such as organic components. Accordingly, a high specific surface area is available, to which the hydrophobic foreign substance particles can accumulate from the liquid to be purified and a good separation of the organic foreign substances from the liquid to be purified is made possible by means of flotation.

As already described in detail above, the present device for generating gas bubbles may also comprise at least one fluidic oscillator, which is provided in one of the gas supply lines 2. By generating an oscillation of the gas at about 9 to 10 Hz, a gas bubble diameter of 45 to 50 μηη is ensured. Accordingly, in combination with the arranged on the hollow shaft gassing a bubble size between 45 to 50 μηη guaranteed.

FIG. 4, in turn, shows a schematic representation of a system 20 for purifying a liquid, in particular water, which comprises at least one of the above embodiments of a device for producing gas bubbles. The side view of the system 20 in FIG. 4 shows a flocculation unit 10 into which the water to be purified and the flocculant are introduced. After mixing the water to be purified with the flocculant, for example using a stirrer, the mixture from the flocculation unit 10 can be introduced via a dividing wall into another, separate section or container 20, in which at least a hollow shaft 20a with four gassing according to the embodiment of Figure 1 is provided.

The present experimental procedure uses waste water that has been treated with humic substances. The totality of organic matter in the wastewater is simulated by humic substances, which are also produced in nature by normal biological decomposition. To flocculate the humic substances contained in the water are especially trivalent ions contained iron and aluminum-containing substances as precipitant. In the present case, a FeCU solution is used as a flocculating agent. After addition of the flocculant using a static mixer, flocculation unit 10 flocculates the humic acids contained in the dirty water by the flocculant FeCU.

The dirty water mixed with FeC is subsequently removed from the flocculation unit 10 in the container 20 comprising the gassing device consisting of a hollow shaft with four gassing discs with a volume flow of 400-700 l / h. initiated.

Air is injected via the gassing device 20a in the container 20 causing microbubbles to form directly in the flocculated water introduced. The gassing or gassing plates of the gassing device rotate in the same direction with a rotational speed of 180 rpm, resulting in a phase shift of 180 °. The microbubbles formed combine with the flocs to form floc-bubble agglomerates, which are subsequently introduced into the downstream flotation cell 30. By the

Addition of the microbubbles to the flocculated organic constituents raise the correspondingly formed agglomerates in the flotation cell towards the surface of the liquid present in the flotation cell 30 and form on the water surface a solid layer which is separated mechanically, for example using scrapers. Below this solid layer, the prepurified water is in the flotation cell 30. The thus pre-purified water is withdrawn using a suitable pump through the arranged in the flotation cell 30 filtration unit 40 and is available as purified water for further processing, such as other desalination processes available , To foul the surface of the To prevent filtration unit 40, air can be passed directly to the surface of the filtration unit 40 via perforated hoses, thereby causing mechanical removal of deposits on the surface of the filtration unit 40.

Claims

claims

1 . Device (1) for generating gas bubbles in a liquid in a container, characterized by

at least one rotatable hollow shaft (3) arranged horizontally in at least one container, wherein the at least one hollow shaft (3) comprises at least one first hollow shaft (3a) with a diameter d3a and a second hollow shaft (3b) with a diameter d3b, where d3a < d3b, so that the first hollow shaft (3a) is disposed within the second hollow shaft (3b);

- At least one vertically arranged on the at least one hollow shaft gassing (4); and

- At least one supply line (2) for at least one compressed gas into the interior of the at least one rotatable Holhlwelle (3), in particular the first rotatable hollow shaft (3a), wherein the compressed gas directly without liquid carrier in the feed line (2) and hollow shaft (3a ) is entered.

Apparatus according to claim 1, characterized in that the at least one first rotatable hollow shaft (3a) consists of a gas-permeable material, in particular a perforated material.

Device according to one of the preceding claims, characterized by at least two mutually horizontally offset staggered rotatable hollow shafts, each with at least one gassing.

Device according to one of the preceding claims, characterized in that at least two, more preferably at least three or more Begasungsschreiben are arranged on the at least one rotatable hollow shaft.

5. Device according to one of the preceding claims, characterized in that on the at least one rotatable hollow shaft between 10 and 100, preferably between 15 and 50, in particular preferably between 20 and 30 gassing discs are arranged.

6. Device according to one of the preceding claims, characterized in that the at least one hollow shaft with a rotational speed between 10 and 250 rpm, preferably between 100 and 200 rpm, more preferably between 150 and 180 rpm is rotatable.

7. Device according to one of the preceding claims, characterized in that the at least one compressed gas is selected from a group consisting of air, CO2, N2, ozone, methane or natural gas.

8. Device according to one of the preceding claims, characterized in that the gas pressure in the at least one rotatable hollow shaft between 1 and 5 bar, preferably between 2 and 3 bar.

9. Device according to one of the preceding claims, characterized in that as gassing a ceramic gassing with a mean pore size between 0.05 μηη and 10 μηη, preferably 0, 1 μηη and 5 μηη, more preferably between 2 μηη and 3 μηη is used ,

10. Device according to one of the preceding claims, characterized in that in the at least feed line (2) is provided at least one device for generating a pulsation of the compressed gas.

1 1. Apparatus according to claim 10, characterized in that the at least one device for Pulsationserzeugung in the compressed gas, a pulsation of the compressed gas having a frequency between 5 and 15 Hz, preferably between 7 and 13 Hz, more preferably between 9 and 1 1 Hz . generated.

12. The apparatus of claim 10 or 1 1, characterized in that the at least one device for Pulsationserzeugung a fluidic oscillator, a automatic valve, in particular a solenoid valve, and / or a positive displacement compressor, in particular a reciprocating compressor, is ..

13. A method for generating gas bubbles in a liquid in a container using at least one device according to one of claims 1 to 12, the method comprising the following steps:

- Introducing a compressed gas in at least one supply line (2), wherein the compressed gas is introduced directly without liquid carrier in the supply line (2);

- Introducing the compressed gas into the interior of the at least one horizontally disposed rotatable hollow shaft (3), in particular the first rotatable hollow shaft; wherein the at least one hollow shaft (3) rotates at a rotational speed between 10 and 250 rpm, preferably between 100 and 200 rpm, particularly preferably between 150 and 180 rpm, and

- Introducing the compressed gas through at least one vertically on the horizontal rotating hollow shaft (3) arranged gassing disc (4) in the liquid to produce gas bubbles.

14. The method according to claim 13, characterized in that the bubbles produced in the liquid have a bubble size between 1 μηη and 200 μηη, preferably between 20 μηη and 80 μηη, in particular between 45 μηη and 50 μηη.

15. The method according to claim 13 and 14, characterized in that in at least one supply line (2) flowing gas using at least one arranged in the at least one supply line for Pulsationserzeugung a pulsation with a frequency between 5 and 15 Hz, preferably between 7 and 13 Hz, particularly preferably between 9 and 1 1 Hz experiences.

16. plant for purifying a liquid, in particular of water, comprising at least one container with a device for producing bubbles according to one of claims 1 to 12, and

 - At least one container in the form of a flotation cell for receiving the blistered liquid with at least one filtration unit for the separation of components contained in the water.

17. A process for purifying water using a plant according to claim 16.