SU1304917A1 - Gravity air classifier - Google Patents

Abstract

The invention is intended for the air classification of bulk materials at the enrichment of minerals and improves the quality of classification by increasing the degree of turbulence in the flow in a vertical pneumatic chamber (PC) 1. Its body is formed successively alternating in height by constricting-expanding sections (C) 2 Each C 2 is designed as a truncated pyramid. Between themselves, C 2 are matched by equal grounds. In PC 1 extensions, flow dividers (P) 7 are coaxially mounted. Each P 7 is made in the form of an octahedron with fastening ribs 8 in the plane of the largest cross-sectional area P 7 rigidly connected to the PC case I. The ribs 8 are placed in the planes of the maximum cross-section C 2. The raw material enters the lower C 2, where under the action of the air flow supplied through the system of nozzles 4 and directed along the axis of the classifier, the separation process takes place. Large particles remain on the perforated grille 3 and are moved along it to the discharge device 6, while small and part of the large particles are picked up by the upward flow and carried away to the upper C 2 where the material is cleaned. Over R 7 flows of aero suspension are directed towards each other. As a result, the flow turbulence increases and conglomerates of cohesive particles break down. I Z.P..F-Ly, 3 Il. $ (L with about with

Description

The invention relates to a technique for the air classification of bulk materials and can be used in the building materials industry, chemical, coal and other sectors of the national household.

The aim of the invention is to improve the quality of the classification by increasing the degree of flow turbulization in the pneumo-chamber.

FIG. 1 shows a diagram of the gravitational pneumatic classifier; in fig. 2 shows section A-A in FIG. one; in fig. 3 - divider, general view.

The gravitational pneumatic classifier contains a vertical pneumocamera 1, the casing of which consists of separate vertically arranged constricting-expanding sections 2, a perforated grill 3 for removal of a large fraction, air supply system 4, loading and unloading devices, respectively 5 and 6, flow dividers 7, ribs 8 fasteners dividers. Each section is made in the form of a truncated pyramid, the sections are matched to each other by equal-sized bases.

Each flow divider is made in the form of an octahedron with fastening ribs located in the area of the largest cross-sectional area of the flow splitter rigidly connected to the body of the pneumocamera. In this case, the fastening ribs are located in the planes of the maximum cross section of the pneumatic chamber sections.

Classifier works as follows.

The source material flows through the loading device 5 into the lower section 2 of the pneumatic chamber 1 of the classifier, where under the action of the air flow supplied through the system of 4 pipes and directed along the axis of the classifier, the separation process takes place. The small particles are picked up by the upward air flow and move upwards, while the large particles remain on the perforated grid 3 and are moved along it to the discharge device 6.

A part of large particles that fall into the air flow core, where the speed is higher than the average, corresponding to the boundary grain, is carried away to the upper sections 2 of the classifier, where material is cleaned up due to the fact that the aero-suspension flows over the divider 7 towards each other, as a result the degree of turbulence of the air flow, the number of collisions between particles increases, therefore large particles are knocked out of the flow core and more intensive destruction of conglomerates of sticky particles occurs .

We consider it necessary to note that in a well-known classifier the flow of air and particles.

The ambient divider has a lower degree of disturbance than the proposed classifier. It is known that stable turbulent flow for an annular channel

obtained at Reynolds numbers 2–3 times larger than for rectangular channels. This means that in the first case the separation should occur either in an unsteady turbulent mode with a small number of flow disturbances, or

high air flow rates. It is also known that the flow rate is related to the particle deposition rate. With an increase in the flow rate, the large product gets large. According to the laws of motion

 air through the pipes and channels it follows that it is the rectangular cross section that is most favorable for the formation of turbulence (separation of the main air flow from the surface of the sections and dividers); thus, cutting the boundary — the interface — between the external flow and the return movement region quickly collapses into a vortex. In the classifier with a rectangular cross section, the residence time of particles in the working area is increased, which improves the quality of the separation of the material.

This form of implementation of the sections allows creating conditions under which the difference in the velocities of particles of different size classes will be maximal.

In the proposed fastening device, the dividers, installed in the maximum section of the section, are carried out by means of fastening ribs (Fig. 1 and 2 - pos. 8). Such fastening of dividers and displacement allows them to receive additional disturbances in the channel bend zone, reduce the cross-sectional area in the widest place and eliminate blockage of the corners in the cross section of the sections.

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Claims (2)

1. Gravitational pneumatic classifier, including a vertical pneumocamera, the body of which is formed by successively alternating in height contractile-widened, sections, flow distributors coaxially installed in pneumocamera expansions, loading and unloading devices, air supply system in a pneumatic chamber, characterized in that, in order to increase the quality of the classification by increasing the degree of turbulence in the flow in the pneumatic chamber, each pneumatic chamber section is made in the form of a truncated pyramid, with lectures are matched to each other by equal grounds, and each flow divider is made in the form octahedra with fastening ribs in the plane of the largest cross-sectional area of the flow splitter rigidly connected to the body of the pneumocamera. 2. A classifier according to claim 1, characterized in that the fastening ribs are located in the ploskosts of the maximum cross section of the pneumatic chamber sections. FIG. 2 Fig.Z