DE19831530C1 - Flotation for cleaning fiber suspensions of used paper for recycling uses additional and larger gas bubbles to carry up the foreign matter with the air bubbles into a floating foam for removal - Google Patents

Abstract

For the cleaning of a fiber suspension (S), to remove foreign matter (5), additional gas bubbles (3) are fed into the suspension with a rising force within the suspension, against gravity, which is at least twice as strong as the flotation air bubbles (2), to carry the foreign matter (5) into a flotation foam (4). The additional bubbles (3) are fed into the suspension (S) below or above the point where the suspension (S) mixed with air bubbles (2) is fed into the flotation vessel (1), so that the larger bubbles (3) are delivered near the outlet of the suspension/bubbles mixture into the flotation vessel (1), and close to the same level as their entry. The larger bubbles (3) are fed into the flotation vessel (1) in a liquid flow. A common mixing tube can be used to deliver flotation bubbles (2) and additional and stronger bubbles (3) into the fiber suspension (S) at different points. The larger bubbles (3) pass into the flotation vessel (1) through openings in a wall, and the normal flotation air bubbles (2) are developed by a turbulence generator and with at least one step diffuser and a static mixer. Flow structures are over the entry points for the larger bubbles (3) to homogenize the upwards bubble flow and distribute the oversize bubbles.

Description

The invention relates to a method for flotation of contaminants from an aqueous Fibrous suspension according to the preamble of claim 1.

Methods of the type mentioned are used to make from a fibrous Suspension at least a part of the contaminant particles suspended therein to be eliminated. As is known, during flotation, the substances to be separated out containing foam or floating mud. A typical application One such method is the processing of one from printed waste paper obtained aqueous paper pulp suspension in which the ink particles are already detached from fibers so that they can float out. This here The flotation process described uses the differences between fiber and undesirable solid particles in such a way that the fibrous material due to its Hydrophilicity remains in the pulp suspension, while those addressed Solid particles are hydrophobic and therefore together with the air bubbles in the Foam. In addition to the ink particles, there are many more Substances that are hydrophobic and therefore separate from the fibrous material by flotation to let. Such substances are in particular glue, fine plastic particles and possibly also resins. If fibers are separated from impurities by the flotation process, So not all solid particles should be sorted out, one speaks of selective Flotation. The term "flotation thinking", which is also used, is usually not used only for the removal of ink particles (ink = ink), but also more generally for the selective flotation of contaminants Fibrous suspensions used.

The state of the art with regard to flotation processes for fiber suspensions has already progressed very far. There are therefore solutions which are quite suitable for removing a large part of the solid particles by flotation. It has been found, among other things, that the bubble size has a very significant influence on the effect of the flotation process. Relevant information can be found e.g. B. in the specialist article R. Klein, et al., "Contribution to the Evaluation of the Influence of the Bubble Size on the Deinking Result", in Wochenblatt für Papierfabrikation 21 , 1994, pages 839 to 845. This publication provides information on how the rate of ascent changes Air bubbles result from their size and other conditions. As is well known, large air bubbles rise faster than small ones.

Another phenomenon, H. Britz, "Flotation Thinking - Fundamentals and System Integration", in Wochenblatt für Papierfabrikation 10 , 1993, pages 394 to 401 deals with this phenomenon with the further indication that it is advantageous to generate a broad spectrum of air bubbles to favor the flotation of a wide range of inks. According to this publication, this is to be achieved by a relatively large process air volume flow (approx. 60%, based on the suspension volume flow), which is mixed into the suspension before flotation.

In many cases, relatively small air bubbles are used because at least for the Removal of a specific part of the contaminant particles is required. Because at the same time a fiber suspension with a relatively high fiber content for economic reasons to be floated, e.g. B. about 2%, it may happen that the small air bubbles intended to be brought into contact with contaminant particles, that is to say could float out. Because of their low tendency to climb, however, that with the small Gas bubble volume is related, the ascent then takes too long. It can even happen that these air bubbles get stuck in the fiber suspension.

It is an object of the invention to create a new flotation process with which it succeeds even with relatively small air bubbles and relatively high consistency Remove contaminant particles reliably and effectively.

This object is achieved by the features mentioned in the characterizing part of claim 1  solved.

With the help of the method according to the invention, it is possible for the addition of Contaminants optimize certain gas bubbles with regard to their size and under such conditions to mix with the suspension that optimal attachment the contaminants can occur in the air bubbles. As you know, there is a specific one Level of energy use required. The additional bubbles formed, however can be adjusted in their rising tendency to the solution of the task, namely the flotation bubbles loaded with contaminant as effectively as possible in the flotation foam to let it rise. It is irrelevant whether a flotation process is used which works only with the help of the earth's gravity or whether the force field through Centrifugal forces are increased. In the latter case terms are as above  and to interpret below regarding the gravity field.

The invention and its advantages are explained with reference to drawings. Show:

Fig. 1, the implementation of the method with reference to a flotation vessel schematically illustrated;

Fig. 2 behavior of the bubbles during flotation according to the invention carried out;

Fig. 3 shows a variant to the bladder addition;

Fig. 4 shows a special mixing tube suitable for the invention.

In Fig. 1, a flotation vessel 1 is shown which has an oval cross-sectional shape here and is substantially closed. The flotation vessel 1 is partly filled with a suspension S containing fibers, into which a mixing tube 8 is immersed. This serves to supply fresh suspension S to be flotated, which is mixed with a gas G in a manner known per se, so that the flotation bubbles 2 can form. The gas G required to form the flotation bubbles is expediently removed from the interior of the flotation vessel 1 . The decisive factor for carrying out the method according to the invention is the addition of further gas bubbles, namely the blowing bubbles 3 , which takes place in an area which lies below the outlet of the fumigated suspension from the mixing tube 8 . For this purpose, fumigation tubes 9 are inserted into the flotation vessel, which, for. B. are porous or provided with openings. You are using a gas G ', e.g. B. air. The blowing bubbles 3 , of which only a few are shown in the area of the introduction into the suspension (also not to scale), have a considerable tendency to rise and very quickly reach the area in which the flotation bubbles 2 (likewise only partially and not to scale) ) are located. By the upward movement of the drive bubbles 3, the Flotationsblasen 2 (not shown here) together with the impurities adhering to them entrained. You then get into the floating flotation foam 4 , which is discharged laterally over a weir and removed as reject R from the flotation vessel 1 . The suspension S 'cleaned by flotation emerges in the bottom region of the flotation vessel 1 . Flow internals 11 are indicated in the flotation vessel, which may be present and then serve to gas bubbles that have become too large, for. B. by unfavorable introduction or by combining several gas bubbles to divide again. You can also even out the upward flow. Such flow internals can, for. B. have the form of coarse grids or a number of bars.

In Fig. 2, the conditions are drawn in an enlarged form, which basically arise when the method according to the invention is carried out. The two types of gas bubbles, namely the flotation bubbles 2 and the blowing bubbles 3 , can be recognized by their different sizes. They float in the fiber suspension S. At least the flotation bubbles 2 are loaded with impurities 5 , but have only a slight tendency to increase due to their small size, especially if the medium surrounding them, namely the fiber suspension S., has a relatively high density for flotation conditions. The blowing bubbles 3 , which flow in with a considerably greater tendency to rise, produce an upward movement, which also includes the flotation bubbles 2 . It can happen that several small flotation bubbles 2 are combined. The application form of the method according to the invention shown here is assumed that zoom drive the blowing bubbles 3 from below to the Flotationsblasen. 2 In other cases it is conceivable that they are added to the flotation vessel at approximately the same height, which will be explained in FIG. 4. However, they can also be introduced into the vessel above the addition point for the fiber suspension mixed with flotation bubbles. They then create a pull. which, under certain conditions, may already be sufficient to accelerate the rise of the flotation bubbles 2 in the desired manner.

In Fig. 3 a somewhat different flotation vessel is shown than in Fig. 1. There, as just stated, the blowing bubbles 3 are fed into the flotation vessel at locations above the outlet of the mixing tube 8 .

Another possibility is to use a special mixing tube 8 ', as shown in more detail in FIG. 4. This offers the possibility of distributing the gas G used with high energy into small flotation bubbles and mixing it with the inflowing fiber suspension S. For this purpose, the gas G is fed in at the first step of a step diffuser 10 , where strong microturbulences form. The downstream steps increase the formation of small flotation bubbles and the accumulation of contaminants on them. The gas G 'required to form the blowing bubbles is also mixed in the same mixing tube, but in a form in which much less energy is used, since it is not important here to generate small air bubbles and bring them together with the contaminants.

Claims (12)

1. Method for flotation of contaminants ( 5 ) from an aqueous fibrous suspension (S), in which
gas-filled flotation bubbles ( 2 ) are generated in a liquid, the impurities in the suspension (S) are attached to the flotation bubbles ( 2 ),
the contaminants ( 5 ) rise with the help of the flotation bubbles ( 2 ) in a flotation container ( 1 ) against the gravitational field,
the contaminants ( 5 ) are collected in a flotation foam ( 4 ) and the cleaned suspension (S ') is removed from the flotation container ( 1 ),
characterized by
that additional gas-filled blowing bubbles ( 3 ) whose buoyancy in the suspension (S) is at least twice as large as that of the flotation bubbles ( 2 ) are added to the fibrous suspension (S). 2. The method according to claim 1, characterized in that the blowing bubbles ( 3 ) below the point in the suspension (S) at which the supply of flotation bubbles ( 2 ) mixed fiber-containing suspension (S) into the flotation tank ( 1 ) is added become. 3. The method according to claim 2, characterized in that the blowing bubbles ( 3 ) in the vicinity of the outlet of the cleaned suspension (S) are added. 4. The method according to claim 1, characterized in that the blowing bubbles ( 3 ) above the point in the fibrous suspension (S) at which the supply of with flotation bubbles ( 2 ) mixed fibrous suspension (S) in the flotation tank ( 1 ) , be added. 5. The method according to claim 1, characterized in that the blowing bubbles ( 3 ) are added at about the same level as the flotation bubbles ( 2 ) mixed fibrous suspension (S) in the flotation container. 6. The method according to any one of claims 1 to 5, characterized in that the blowing bubbles ( 3 ) are introduced together with a flow of liquid into the flotation container ( 1 ). 7. The method according to claim 1, characterized in that both the flotation bubbles ( 2 ) and the blowing bubbles ( 3 ) of the fiber-containing suspension (S) are mixed in separate places in a common mixing tube ( 8 '). 8. The method according to any one of the preceding claims, characterized in that the addition of the blowing bubbles ( 3 ) through openings provided with openings ( 6 ), while a turbulence generator is used to admix the flotation bubbles ( 2 ). 9. The method according to claim 8, characterized in that a turbulence generator with at least one step diffuser ( 10 ) is used. 10. The method according to claim 8, characterized, that a static mixer is used as a turbulence generator. 11. The method according to any one of the preceding claims, characterized in that above the addition point of the blowing bubbles ( 3 ) in the flotation tank ( 1 ) fixed flow internals ( 11 ) with which the rising flow is homogenized. 12. The method according to claim 11, characterized in that the oversized gas bubbles are divided with the flow internals ( 11 ).