SU1263377A1 - Centrifugal classifier - Google Patents

Abstract

The invention is intended for the pneumatic classification of polydisperse materials in the field of centrifugal forces and can be used in the construction, chemical and other industries. The purpose of the invention is to increase the efficiency of classification due to the operative withdrawal of large fractions from the spiral chamber (SC) of the air distribution and particulate material. For this, around the periphery of the SC 2 there is a concentric slit 14, which is spirally formed. Under the central nozzle (P) 5 coaxially installed the main drive. A package of additional disks with central holes mounted coaxially above it is rigidly connected to it. The disks are fixed on the drive shaft so that radial-tangential channels (K) 10 are formed between them, and axial KI is centered in the center. Air and the initial aerosol mixture are supplied to SC 2, respectively, according to P 3 and 4, tangent to its walls, where The image of the so-called vortex flow through K Yu and 11 in P 5. In relation to P 3 and 4, the central P 5 is under reduced pressure. In the field of centrifugal forces of the vortex flow material separation occurs. Croup (Particles, settle on the side wall 13 of the CK 2, slide on it and fall through the shell 14 into the bunker 7, and the thin ones fall into K 10 and then through K II, P 5 and the cochlea 6 are removed from the apparatus. 1 h . P. f-ly, 2il. GS a oo with | vl

Description

The invention relates to devices for the pneumatic classification of polydisperse materials in the field of centrifugal forces and can be used in the building materials industry, chemical, pharmaceutical and other sectors of the national economy.

The aim of the invention is to improve the classification efficiency due to the operative withdrawal of large fractions from the spiral distribution chamber.

FIG. 1 shows a classifier, a general view; in fig. 2 shows section A-A in FIG. one.

The centrifugal classifier comprises a housing 1, a spiral air distribution chamber 2 and a dispersed material, air supply connections 3 tangential to its walls, and 4 initial air mixtures, a small fraction central air outlet 5, an exit scroll 6, and a coarse product hopper 7.

Inside the spiral chamber 2 there is a rotor consisting of a disk pack 8 fixed on the drive shaft 9 with the formation of radial-tangential channels 10 between them, and axial channel 11 in the center.

Between the edge of the flat bottom 12 of the spiral chamber 2 and the inner surface of its side wall 13 there is a spiral concentric slit 14 for outputting large fractions.

Classifier works as follows.

The air flows entering the spiral chamber 2 through nozzles 3 and 4 and the initial aerosol mixture are twisted to form a so-called vortex flow through the rotor channels 10 and 11 into the central nozzle 5, which is under reduced pressure relative to nozzles 3 and 4. In the field of centrifugal forces of the vortex flow separation of the dispersed material occurs: relatively large particles, overcoming the resistance of the air environment, are displaced to the periphery of the vortex, where they are deposited on the side wall 13 of the spiral chamber 2, slide along it under the action of gravity and fall through the spiral slot 14 the bunker 7 of the coarse product, fine particles, the trajectories of which slightly deviate from the air flow lines, get into the radial-tangential channels 10 of the rotor, where they are subjected to an additional clearer one from fission from large particles, and then through the axial channel 11, the nozzle 5 and the cochlea 6 are removed from the apparatus.

The coarse product display system used in the classifier is practically not

distorts the structure of the vortex flow and ensures the rapid removal of coarse particles from the separation zone. This creates conditions for highly efficient classification. As is known, the operation of the classifier is characterized by a separation curve, which indicates how much of the particles of the initial dispersed material are carried into one or another (for example, thin) product. Experimentally, the separation curve is determined by the yield values of a product by fraction, i.e. narrow size range of dispersed material. Based on the separation curve, the separation boundary and

classification efficiency (clarity of separation).

One of the most simple but informative classification efficiency indicators is the Eder-Meier clarity of separation & 75 / §25, which is a ratio of particle sizes that are 75% and 25% carried to a thin product. For most industrial classifiers, this figure does not exceed 0.5, for laboratory - 0.7. When comparing classifiers for this indicator, it should be borne in mind that the weaker indicator S 65/535 is often used, which, with the same classification efficiency, has a greater value than 575/525.

Tests of the proposed classifier showed that it provides clear separation of polydisperse material / 25 at the level of 0.75. Indicator b65 / 535 for the classifier is at the level of 0.85.

Claims (2)

1. A centrifugal classifier, comprising a housing with a spiral chamber for distributing air and a particulate material with a concentric slot for outputting large fractions, a central nozzle for withdrawing small fractions from the housing, a disk mounted in the housing under the central coupling coaxially with it, characterized in that increasing the efficiency of classification due to the operative withdrawal of large fractions from the spiral distribution chamber; the concentric gap is made in a spiral located along the periphery of the spiral chamber air and particulate matter. 0 2. A classifier according to claim 1, characterized in that it is provided with a package of additional disks with central apertures coaxially mounted above the main and rigidly connected with it, and a disk rotation drive. eleven 13 P (PU2.2