CH623754A5 - Air classifier - Google Patents

Description

The invention relates to an air classifier from at least one chamber designed as a zigzag channel with at least two floors, which is provided at the upper end with a feed opening for the visible material and at the lower end with a discharge opening for the coarse material.

Such an air classifier is known from DT-AS 1 270 380 and is designed and constructed for classifying a defined material into a very specific number of fractions of different grain sizes, taking into account the specific and aerodynamic properties of this material. In order to achieve this goal, the known classifier requires a number of stages which corresponds at least to the number of fractions of different grain size or different aerodynamic properties to be obtained. Since the design of this air classifier has to be carried out in a precise adaptation to the properties of the feed material, an optimal classifying result can no longer be achieved if this known air classifier is subjected to a material with changed specific and aerodynamic properties.

Knowing the range of different sorting features to be expected overall, it is common to provide the air classifier with a corresponding number of levels, each of which is structurally matched to the properties of a sorting feature. This measure ultimately finds its limits both in terms of the overall height and in the acquisition and operating costs and thus in the efficiency of the classifier.

The above-mentioned criteria for the limit of economy and feasibility are particularly noticeable in classifiers that are to be built for processing mixtures of substances with a largely unknown composition of substance types and substance proportions. In this respect, the extremely difficult goods include, in particular, municipal waste, which is divided into reusable fractions, e.g. As paper, glass, plastics, textiles, rubber and the like. To be separated, which are often contained in so-called household waste in completely unpredictable proportions. On the one hand, this waste material can contain a large number of different substances, i.e. this waste material has a variety of sorting characteristics, but also only the separation of only one type of substance, e.g. B. paper, of impurities contained therein, e.g. B. wood chips to be performed. Although in practice the maximum number of sorting features and their simultaneous handling by the sifter is understandably rare in relation to the total operating time, the sifter must be able to optimally take into account each of the maximum possible soting features, a conventional sifter for the The above-mentioned case of waste composition has six individually designed viewing levels, the full utilization of which is only used to a minimal extent, which significantly affects economic efficiency, quite apart from the fact that a relatively large amount of space is required.

The invention has for its object to provide an air classifier of the type mentioned, which optimally processes a maximum of different sorting features, in particular those with aerodynamically only slightly different properties, with a minimum of viewing levels. This object is achieved according to the invention in that a suction nozzle provided for fine material is arranged above the upper floor, which is pivotably mounted about a horizontal axis and is designed as an air-filled box with a perforated working surface, in the channel wall opposite this. This design of a sifter stage can make it possible in a surprisingly simple manner to vary the characteristic and to optimally adapt it to the respective conditions. By changing the inclination of at least one sifter bottom, the dwell time of the material sliding past the suction nozzle and the distance between the bottom and the suction nozzle can be changed. In addition, by adjusting the strength of the air flow emerging from the perforated work surface of the floor, the mixture to be sifted can be separated, depending on the density of the different parts of the material, into material layers which are more or less distant from the floor and are kept in a turbulent state of suspension. The material that is specifically kept in this way in a high, turbulent, floating state that is optimal for its separation, namely the specifically lighter or the more aerodynamically suspended, can be detected and suctioned off as it passes through the nozzle. On the other hand, the material part (s), which are deliberately kept in a low, turbulent state of suspension, cannot be detected by the nozzle and, after leaving the swiveling base, either reach the discharge end or a further separation stage.

The removal of the upper, in high levitation ge5

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The layer of fabric held can be optimal if the suction nozzle and the bases have the same width as the associated chamber.

A particularly favorable design results from the design of the box as a cylinder sector, since a streamlined shape is thereby achieved and at the same time the air gap between the duct wall carrying the box, i.e. the wall, which is connected to the pivotable floor, and the cylinder surface of the box remains unchanged when pivoting, which has a particularly advantageous effect on the required sealing measures. This design of the box also allows a particularly versatile variant to be realized, in which the box can be swung out of the chamber, so that a free passage for releasing bridging and material jams can be created in the chamber.

The inventive design and mutual association of suction nozzle and upper floor can be further developed in the sense of a further refined influence on the visual effect by additional measures within the scope of the invention. A precise setting of the effectiveness of the suction process on the material layer to be removed can be achieved if the swiveling of the suction nozzle over a range of 60 °, starting from the horizontal, influences the suction component which acts directly.

If it turns out during operation that the aforementioned suction draft component has the optimal direction, but acts at too high a speed, this can be countered in a further embodiment of the invention in that the suction nozzle has at least one false air opening which can be adjusted and closed in cross section . In addition, the visual effect can also be advantageously influenced by the fact that the duct wall connected to the upper floor has at least one air inlet opening which can be adjusted and closed in cross section, just above the same. This air inlet opening is only opened under special circumstances because, understandably, the supply air - outside the working surface of the upper floor - is directed in counterflow to the direction of the coarse material in order to loosen it up again during the downward movement. However, if the coarse material is prevented from moving downwards by the supply air supplied in counterflow or even parts thereof get into the airflow of the suction nozzle, this can be prevented by opening the air inlet opening, because this reduces the amount of air brought in in counterflow and its speed. A further possibility of using the air inlet opening is that a fluidic driving effect is exerted on the material layer to be skimmed off by the suction nozzle by means of the supply air supplied through it. This can e.g. B. then be of advantage if the inclined position of the upper floor and thus the force of gravity caused by the driving effect must be reduced in order to achieve a more pronounced gradation of the suspended layers by an extended residence time of the material.

Finally, in the duct wall connected to the upper floor, a cross-section adjustable and closable supply air opening can also be provided just below the box, which is then opened when a greater swirling of the coarse material falling from the upper floor is required.

The viewing chambers designed according to the invention can offer in an excellent way the possibility of creating air classifiers with optimal efficiency at comparatively low manufacturing costs and increased additivity or possible use if several chambers of the same design are arranged vertically one above the other, with the chambers - apart from the uppermost chamber - are connected with their feed opening to the discharge opening of the chamber located above. A diverse adjustability of a viewing level can be achieved. In contrast to comparable known classifiers, the number of possible sorting criteria for a classifier composed of several stages can be a multiple of the number of its individual stages. Therefore, a classifier according to the invention can build considerably lower than a conventional classifier for a certain number of sorting features.

Further details of the invention are described below with reference to an embodiment shown schematically in the drawings. Show it:

1 a wind sifter composed of three stacked chambers in vertical section,

Fig. 2 shows a section along the line II-II through the air classifier according to Fig. 1 and

3 shows a flow diagram of a sorting system containing an air classifier according to FIG. 1.

The wind sifter 1 is constructed from three consecutive, uniform viewing elements 2, each consisting of a chamber 3 with a substantially rectangular cross section, which has a feed opening 4 for visible material at the upper end and a discharge opening 5 for coarse material at the lower end. If, as in the example shown, the wind sifter consists of several viewing elements, the discharge opening 5 of the upper chamber is identical to the feed opening 4 of the chamber below it. In the chamber 3, two floors 6, 7 are fastened to or included in channel walls 8, 9 lying opposite one another in such a way that they form a zigzag channel for the visible material. The upper floor 6 is designed as a box 10 with a perforated work surface 11 and is pivotally mounted in bearings 13 by means of pins 12. The handle 14 shown in connection with one of the pins 12 is intended to symbolically indicate the pivotability. In the illustrated embodiment, the work surface 11 is up to about horizontal and down to about vertical, i.e. can be pivoted about in line with the channel wall 8. In order to achieve an equally good seal between the channel wall 8 and the box 10 in each position of the bottom 6, the latter is designed as a cylinder sector. The compressed air emerging from the perforated work surface 11 is fed to the box 10 via a connecting piece 15.

Above the bottom 6 and opposite this, a suction nozzle 16 for fine material is arranged in the channel wall 9. The suction nozzle 16 is pivotally connected to the channel wall 9 via a flexible holder or a joint part 17, so that it can be pivoted approximately from the 60 ° position shown to the horizontal position. Furthermore, the suction nozzle 16 has a lateral false air opening 18 which can be opened to the surroundings and whose cross section can be adjusted and closed by means of a hinged cover 19. The floors 6, 7 and the suction nozzle 16 have the same width b as the chamber 3. Just above the upper floor 6 in the duct wall 8 there is also an air inlet opening 20 which can be opened outwards and which can be adjusted in cross section by means of a pivoting flap 21 is lockable. Another supply air opening 22 for outside air is finally arranged just below the box 10 and can be regulated and closed in cross section by means of a flap 23.

According to FIG. 3, a blowing or sifting air fan 24, the pressure line 25 of which is connected to the three connecting pieces 15 of the boxes 10, supplies the air flow required for generating turbulent material floating layers. Each suction nozzle 16 is on the suction side of a conveyor fan

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26, 27, 28 connected, the blow lines 29, 30, 31 each lead to a centrifugal separator 32, 33, 34. The fine material separated from the conveying air in the separators arrives in containers 35, 36, 37, while the conveying air is either expelled into the open via openings 38 or fed back into the fan 24 as recirculating air.

One possible way of operating the prescribed air classifier is described below using the example of a process sequence:

The mixture to be sorted should contain, for example, paper, cardboard, wood and metal residues. It is first fed via a feed belt 39 to a shredder 40, which first crushes the components to a particle size with a maximum edge length of five centimeters. This measure makes the subsequent screening process largely independent of the aerodynamic characteristics of the particles, so that the screening can be carried out essentially on the basis of different material densities. A fan 41 arranged downstream of the shredder 40 conveys the shredded mixture into a cyclone 42, the solids outlet of which opens into the filling shaft 43 of the air classifier 1.

In the air classifier 1, the amount of air sucked out by the suction nozzles 16 is equal to the sum of the partial air amounts supplied from different directions, which result from the air amounts flowing out of the work surfaces 11, from the counter-air flow sucked in via the lowermost discharge opening 5 and, if appropriate, from those through the false air openings 18, the air inlet openings 20 and / or the supply air opening 22 assemble sucked air streams.

In the top view level, the flow velocity of the air emerging from the working surface 11 is set such that the mixture separates into superimposed layers, which are kept in a turbulent floating state, depending on the density of its different components, so that the lightest fraction, in the present example paper and Plastic films that form the top layer. When the material flow stratified in this way runs past the suction nozzle 16, the light fraction is detected by the nozzle, suctioned off, and fed via the conveying fan 26 and the blow line 29 to the material separator 32, which releases the fine fraction into the container 35 after the conveying air has been separated off.

The pivotability of the box 10 and the suction nozzle 16 explained at the beginning makes it possible to achieve an optimal interaction of the spacing of the named components with the flow directions on the one hand for the respective material conditions. The residue mixture running over the edge 1 la reaches, in particular close to

Edge 1 la, into a vortex flow generated by the rising counter-air flow, which provides for a further loosening of any caked goods. As a result, further light fraction is driven into the suction nozzle 16 of the upper 5 stage. However, the counter air flow should only be so strong that it is unable to carry the heavy fractions intended for the subsequent visual stages.

If the suction draft prevailing at the inlet of the suction nozzle is nevertheless so large that even heavier fractions are drawn off, this can be regulated by opening the hinged cover 19 of the false air opening 18 to a greater or lesser extent.

The undesired suction of heavier fractions can, however, also be caused by an excessively strong counter air flow, which prevents part of the gravity fraction from falling down. In this case, it is expedient to open the swivel flap 21 of the air inlet opening 20 to such an extent that, on the one hand, the amount of air flowing in reduces the counter-air flow and, on the other hand, a driving effect is exerted on the material layer to be skimmed off by the suction nozzle 16.

If, on the other hand, the counter-air flow is so weak that the heavier fraction falls too quickly and is not whirled up and loosened enough, then an additional air stream can finally be used to increase the counter-current by opening the flap 23 of the supply air opening 22.

The falling heavier fraction does not immediately fall vertically into the next level of vision, but goes to the bottom floor 7 next to it. This measure extends the line of sight to the next level of vision while reversing the direction, so that the object to be broken down is intensified comparatively low height of the classifier is achieved.

35 The heavy cardboard is separated in the middle view level. For this purpose, both the inclined position of the work surface 11 and the suction nozzle 16 and the individual air streams can again be optimally adjusted to the needs of this material. Due to its versatile adjustability, the middle viewing level can also be operated in such a way that the wood components are already separated there together with the heavy cardboard. In this case, the lowest level of vision would be superfluous, so that, as indicated by dash-dotted lines in FIG. 1, the box 10 can be pivoted out of its chamber 45 3 so that the remaining heavy fraction can freely fall out of the classifier onto the conveyor belt 44 below.

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Claims (9)

623 754 1. Windsich ter from at least one chamber designed as a zigzag channel with at least two floors, which is provided at the upper end with a feed opening for the visible material and at the lower end with a discharge opening for the coarse material, characterized in that one for fine material The suction nozzle (16) provided is arranged above the upper floor (6), which is pivotably mounted about a horizontal axis and is designed as an air-loaded box (10) with a perforated working surface, in the channel wall (9) opposite this. 2. Windsich ter according to claim 1, characterized in that the suction nozzle (16) and the bottoms (6, 7) have the same width (b) as the chamber (3). 2nd PATENT CLAIMS 3. Air classifier according to claim 1 or 2, characterized in that the box (10) is designed as a cylinder sector. 4. Air classifier according to one of claims 1 to 3, characterized in that the box (10) can be swung out of the chamber (3). 5. Air classifier according to one of claims 1 to 4, characterized in that the suction nozzle (16) can be pivoted upwards over a range of 60 °, starting from the horizontal. 6. Air classifier according to one of claims 1 to 5, characterized in that the suction nozzle (16) has at least one cross-section adjustable and closable false air opening (18). 7. Air classifier according to one of claims 1 to 6, characterized in that the channel wall (8) connected to the upper bottom (6) has at least one air inlet opening (20) which can be adjusted and closed in cross section just above the same. 8. Air classifier according to one of claims 2 to 7, characterized in that the duct wall (8) connected to the upper bottom (6) has at least one supply air opening (22) which can be adjusted and closed in cross section, just below the box (10). 9. Air classifier according to one of claims 1 to 8, characterized by a plurality of vertically superposed, identically shaped chambers (3) which, apart from the uppermost one, are connected with their feed opening to the discharge opening of the chamber (3) located above them.