AT391635B - GRAVITY SIGHTER - Google Patents

Description

No. 391 635

The present invention relates to the air sifting of various bulk materials in the upstream air and in particular relates to a welding classifier.

The invention can be used particularly effectively in chemistry, mining, construction, casting production and in other branches of industry in which bulk goods are used, which are divided into two or more 5 products according to the grain size, preferably in a range from 0.05 to 1 mm must be separated.

The creation of highly effective facilities for the separation of bulk goods is a current problem, because with the development of new and the improvement of known technologies, for example in powder metallurgy, in the production of molding materials, etc., increasing demands are placed on the size composition of raw materials, semi-finished products and Products. One of the 10 most promising separation methods is wind sifting. A cascade gravity classifier, which is designed in the form of a large-scale housing that is divided by vertical partition walls into a series of shafts that lie above an inclined perforation floor, has proven itself in practice for air classifying bulk goods. The material is sifted in the shafts either by means of sheath elements (SU-A-787113) arranged on the inner walls of the shaft, or a zigzag design 15 of the shaft walls (GB-B-2623038) is provided. The following characteristic values can be achieved through such a structural design of the classifiers: the effectiveness, which is characterized by the Eder-Mayer characteristic number χ = & η / / & 25 * 100, is 70 to 75% (where d-75, d2 $ - sizes of the grains, which are sifted through 75% and 25% respectively into the fine material) with a throughput concentration of the starting material μ = 2.0 to 2.5 kg / m ^ and a throughput of 60 to 100 t / h. The maximum energy consumption is 2.5 kW per 11 20 raw materials. In the above-mentioned classifier types, the separation of the bulk goods is based on the generation of a fluidized bed by means of a gas stream rising through the perforation floor. When whirling, the material moves in the direction of inclination of the perforation base. It is separated into fine and coarse fractions under the influence of gravity and aerodynamic resistance. The fine grain fractions are discharged into the viewing shafts by the upstream air, where they are additionally sighted and freed from random coarse grains. Thus, a multiple screening, both of fine and coarse material, takes place in the above-mentioned constructions, as a result of which good effectiveness is achieved.

However, the above-mentioned classifier types are not effective enough if the grain size composition of the bulk goods has to meet increased requirements, for example in the production of molding materials, grinding and polishing powders, etc. This can be explained by the fact that the distribution of the material over the length of the perforation bottom is uneven; the material accumulates much more at the loading device, especially in cases with a higher throughput concentration; d. H. as the throughput concentration increases, the classifier throughput increases in proportion and at the same time the separation efficiency decreases with the throughput increase. These disadvantages are associated with an ineffective function of the viewing shaft-perforation base assembly. The separation time of the starting material on the 35 perforation base in fine and coarse fractions depends on the height of the fluidized bed of the material: the higher the fluidized bed, the worse the separation into coarse and fine fractions and the more time it takes to blow out the fine fractions required from this layer. Since the small gas flows in the fluidized bed have a random, constantly changing direction between the Gutkömem, with a high fluidized bed there is a greater chance that the fine grains are stopped by the coarse ones, 40 d. that is, the higher the layer of material on the perforation floor, the smaller the probability that the fine grains leave the layer.

A gravity classifier (SU-A-1015935) is known which has a hollow housing which contains an inclined perforation base with holes for the gas flow outlet. The bottom is inclined in the direction from the loading device attached to the classifier housing for the feed material feed to the device for discharging coarse material. Vertical dividing walls are provided in the housing, through which viewing shafts are formed. In the shafts, dividing elements are fastened one above the other on the side walls and partitions. The loading device for the feed material feed into the classifier is arranged above the upper edge of the housing base In the housing there is a device for discharging coarse material, which is attached to the bottom bottom edge. In the upper part of the housing there are nozzles for discharging the gas flow and the fine material 50 Feed material is fed into the perforation floor via a loading device, through which air is blown into the viewing shafts. A fluidized bed of the starting material is produced on the perforation base and then moves in the direction of inclination of the perforation base towards the discharge device. During whirling, the fine fractions are gradually discharged into the viewing shafts, where they are exposed to the repeated action of the sheath elements and freed from coarse particles. The coarse fractions of the starting material move into the discharge device as they move over the perforation floor in its lower part.

A similar classifier is described in DE-Al-36 26 053, in which a channel provided with a perforation base is provided, which is arranged in the middle of the viewing shaft, a gap being present between this channel and the housing walls. 60 The classifiers of the known designs have a low separation efficiency with increased throughput. With classifiers, as described in SU-A-1015935, the entire source material is distributed over the -2-

No. 391 635

Perforation bottom, and with an increased throughput of the classifier, the fluidized bed height increases accordingly. With such a design of the classifier, the discharge time of the fine fractions from the fluidized bed is rather long, and therefore not all fine fractions are discharged during the passage of the material through the perforation floor, and the coarse material is contaminated by part of the fine fractions. With increasing throughput of the classifier, the fluidized bed height on the perforation floor increases, and consequently the discharge of the fine fractions from the fluidized bed is reduced, i. H. the coarse material is contaminated more by fine fractions

In a classifier, as described in DE-Al-36 26 053, there is a partial displacement of the air throughput to the gaps between the channel and the housing when the load on the material to be screened is increased with the associated increase in the resistance of the fluidized bed . This disturbs the formation of eddies, the operation of the classifier becomes inconsistent and the separation quality is reduced

A differently designed wind classifier is described in DD-A3-251 247. In this air classifier, several block-shaped groups of flat zigzag channels are provided one above the other, each group containing a packet of parallel channels and the block-shaped groups being offset by 90 ° to one another. With this air classifier, the material to be sifted is fed to the uppermost group of channels by gravity; the viewing airflow is supplied from below, i.e. H. introduced into the bottom group of channels from below. At the lower cross-section of the lowest group of channels, the coarse grain falling down also leaves the classifier; the visible air is extracted together with the dust on the top of the top group. In this known air classifier, no perforation bottom is provided.

The invention has for its object to provide a gravity classifier equipped with a perforation for bulk materials, the structural design ensures the regulation of the fluidized bed height of the bulk material and an extension of the residence time of the material in the classifier, thereby increasing the effectiveness of the starting material separation.

The object is achieved in that in a gravity classifier for bulk goods, which has a hollow housing which has an inclined perforation base with holes for gas flow passage, in the housing attached and superimposed cutting elements, a loading device attached above the upper edge of the housing base for the feed material in contains the classifier, a device for discharging coarse material fastened in the lower part of the housing, at least one connecting piece arranged in the upper part of the housing and connected to the latter for discharging the gas flow with the fine material, according to the invention at least one grid is arranged transversely to the upstream direction, that covers the passage cross section of the housing and is connected to the latter.

In such a constructive design, the arrangement of the grating over the perforation base distributes the starting material over the grating and the floor, a fluidized bed of the material being formed on each grating and on the floor a mutual mass exchange and the formation of fluidized beds on all grids and on the floor, which significantly increases the time the material stays in the classifier. Practice has shown that the yield of fine fractions increases with the increasing residence time of the starting material in the classifier

In addition, the dependence of the separation efficiency and the increasing throughput from each other is expressed much weaker in the classifier provided with the grids above the perforation base, which can be explained by an even distribution of the starting material over all grids and by the formation of thin fluidized beds on all grids

It is expedient that the passage cross section of each subsequent grille of the classifier in the gas opening direction is equal to or larger than the passage cross section of the previous grille.

With such a design of the passage cross sections of the grids, finer fractions accumulate on the upper grids because the gas flow rate through the upper grids is lower than through the lower ones, and consequently the separation limit is shifted in favor of the fine fractions. Here and further in the text, the term " separation limit " understood the average diameter of the grains, which are obtained from the raw material in the classifiers in equal proportions into the fine and the coarse separation product. The separation limit in gravity classifiers is usually regulated by the air flow rate

In addition, the above-mentioned construction of the classifier increases the throughput at a certain value of the separation efficiency by increasing the throughput concentration of the starting material, because the concentration in the classifying ducts and on the entire surface of the grid and the perforation base is balanced. In a concentration range of 2 to 6 kg / m ^ the separation efficiency remains practically constant and is approximately 80 to 85% according to Eder-Mayer.

In the classifier according to the invention, the following results were obtained, for example, in the separation of molding sand, the effectiveness according to the Eder-Mayer index χ = 85% at a good concentration μ = 2 kg / nr * and a throughput of 30 t / h and χ = 80% at μ = 6 kg / m ^ and the same throughput.

Further objects and advantages of the invention are explained on the basis of a concrete exemplary embodiment with reference to the accompanying drawings, in which it shows -3-

Claims (2)

No. 391 635 Fig. 1 shows a schematic representation of a gravity classifier according to the invention for the separation of bulk material according to the grain size, vertical section in the direction of movement of the material, with partial tears; Fig. 2 shows the same classifier according to the invention in an isometric view, with partial tearing in the lower part on the perforation base and on the grids. The gravity classifier according to the invention, which is intended, for example, for molding sand separation according to the grain size, has a hollow housing (1) (FIG. 1), which is divided by vertical partition walls (2) into a series of viewing shafts (3), in which separating elements are stacked are arranged. The cutting elements are in the form of inclined plates (4) which are fastened to the vertical partitions (2) and to the housing side walls. In the lower part, the housing (1) is covered with an inclined perforation base (5), through the holes (6) of which a gas flow enters the classifier. On the wall (7) of the housing (1) on the side of the upper edge (8) of the inclined bottom (5), a loading device is attached, which is designed in the form of an inclined groove (9). A discharge device, which has the shape of a hollow socket (11), is fastened to the lower edge (10) of the perforation base (5). In the upper part of the housing (1) of the gravity classifier, nozzles (12) for discharging the gas flow with the fine material are fastened. The number of nozzles (12) can match the number of viewing shafts (3). The fine fractions and the gas flow can also be removed via a single nozzle (12). In addition, the viewing shafts (3) can be combined in pairs or in another way through the connecting pieces (12). Grids (13) (FIG. 2) are arranged and fastened in the housing (1) across the perforation base (5) transversely to the direction of gas upflow. The passage cross section of each subsequent grille (13) in the gas upstream direction is equal to or larger than the passage cross section of the previous grille (13). With such a design, the air flow velocity is evenly distributed over the height. The direction of movement of the gas flow through the perforation base (5) and the viewing shafts (3) is generated by a fan (not shown in FIG.). The gas-dust mixture is produced in special devices, for example in a cyclone (not shown in FIG.). Cut. Conveyor belts (not shown in FIG. 1) are used, for example, for the task of the starting material, the removal of the separation products. The classifier functions as follows. The starting material is fed via the inclined groove (9) onto the upper edge (8) of the perforation base (5) of the housing (1). As a result of a negative pressure in the housing created by the fan, the sand is lifted into the cavity of the shafts (3) with the air flow rising through the holes (6) in the base (5). A fluidized bed is created and the material is redistributed between the grids (13). Redistribution of the sand into coarse and fine fractions begins under the influence of resistance and gravity. The fine fractions are discharged into the viewing shafts (3) by means of air currents, where they are subjected to a multiple separation effect of the inclined plates (4) and are freed of coarse grains of sand which are accidentally caught by the air flow. Then the fine fractions are discharged into the cyclones via the nozzle (12), separated from the air and transported away by the conveyor belt. Since the starting material is divided into fluidized beds on all of the grids (13), there is an intensive removal of the fine fractions from the layers, an intensive mass exchange between the fluidized beds on the grids (13), which increases the residence time of the material in the classifier, which the separation efficiency increases. When whirling, the material moves in the direction of inclination of the perforation base (5). When moving in the fluidized bed on the inclined perforation floor (5), the coarse fractions free themselves from the fine particles and are led out of the classifier via the discharge nozzle (11) and transported by the conveyor belt. The fact that the fine fractions are more intensively removed from the fluidized beds of the material distributed on the grids, in contrast to the prototype, a higher separation efficiency is achieved in the gravity classifier in the construction according to the invention. PATENT CLAIMS 1. Gravity classifier for bulk goods, which has a hollow housing, which has an inclined perforation base with holes for gas flow passage, in the housing fixed and superimposed sheath elements, a loading device attached above the top edge of the bottom of the housing for the feed material feed into the classifier, one in Lower part of the housing fastened device for discharging coarse material, at least one in the -4- 10 No. 391 635 upper part of the housing and connected to the latter connecting piece for discharging the gas flow with the fine material, characterized in that at least one grid above the perforation bottom (13) is arranged transversely to the upstream direction, which covers the passage cross section of the housing (1) and is connected to the latter. 2. Sifter according to claim 1, characterized in that the passage cross section of each subsequent grille (13) in the gas upstream direction is equal to or larger than the passage cross section of the previous grille (13). Including 2 sheets of drawings 15 -5-