SU1265002A1 - Pneumatic multicolumn classifier - Google Patents

Abstract

. PNEUMATIC MULTI-. LON KPASSIADKATOR, which includes a number of vertical columns with a reloading of shelves, connected by overflow pipes, a device for the supply of source material, collections of finished fractions, a pipe for air supply, from. In order to increase the separation efficiency due to the intensification of the material dispersion while stabilizing the specific energy consumption, the classifier is equipped with perforated guide shelves, each column is made of dispersion sleeve and separating parts of different flow sections, the inlet end of the bypass branch pipe is connected to the separation section, and the separation end of the cross section is connected to the separation section. with the dispersing part, and the output end with the dispersing part of the next column, with the perforated direction of the regiment a is installed at the interface of the separating and dispersing parts. I of each column is from the side of the bypass (with a nozzle and with a gap relative to the opposite wall of the column. 2. Classifier according to claim 1, which is the flow cross section of the dispersing part of the column is 2-40 times less than the separating one.

Description

The invention relates to the pneumatic classification of various si-beams of materials in an upward air flow, intended for separating powders with a particle size of less than 2–3 mm into two or more products along the boundary from 30–40 to 1.0 mm (the use of a classification is particularly effective). ) a for separating difficult materials that contain a significant amount of particles less than 20 microns and are capable of forming stable conglomerates and can be used to divide the puchas of materials into two or more fractions in the metallurgical, chemical mountain, construction and other industrial sectors. The purpose of the invention is to increase the efficiency of separation of 5G due to the intensification of the dispersion of the material while stabilizing the specific energy consumption. The drawing shows a pneumatic multi-column classifier, a general view. The pneumatic multi-column classifier consists of several columns, each of which is divided into separating 1 and dispersing 2 parts. The separating part is a vertical channel of rectangular cross section, inside of which pouring elements, for example, pouring shelves, are installed. The flow section of the separating part in the lower section is 20-40% less than in the upper section. The dispersing part is also a vertical channel with pouring shelves, its cross section is significantly (20-40 times) smaller than the section of the separating part. In the dispersing part there is a hole for entering the classified material. Between the separating and dispersive portions of the column, a guide shelf 3 is installed, between the end of which and the wall of the separating part there is a gap for the passage of the air mixture. In the lower part of the separating part there is an overflow pipe 4 which is connected to the dispersing part of the subsequent clas sification stage and serves to transfer the intermediate product. The last stage pipe is connected to the bunker 5 of a large product. Non-return valves 6 are installed in the perpendicular inlet pipes 6. Bunkers of a large product are also installed under the dispersing parts of the columns. Hoppers have air holes. The upper part of the separating part of the columns is connected to dust precipitation cyclones. The air movement in the classifier is disturbed by the discharge generated by the fan. Classifier works as follows. The source material is fed into the dispersing part 2 of the first stage of classification by a hermetic feeder. The air flow moving in the mine picks up the particles of the material and carries them up. Due to the higher, than in the separating part, the speed of the air flow, the raw material almost completely entrains them in the separating part 1 to only the largest particles, the size of which significantly exceeds the separation boundary, fall into the bunker 5 of the large product located under the dispersing part. The particles of the material picked up by the air stream, when they move upwards along the dispersing part, are subjected to intense (guided by air vortices in the spaces under the pouring regiment III, collide with each other, hit the shelves and walls of the column. At the same time, the aggregates in the material and separation of particles from each other. The thus prepared air-flow through the gap between the guide shelf 3 and the wall of the apparatus enters the separation part of the column. The speed of the air flow in the lower the section of the separating column, the part of the column is 20-40% higher than that required for separation along a predetermined boundary, due to which most of the small particles are carried by the air stream into their upper separation from the large ones. Large particles, non-destroyed aggregates and some of the small things overcome the resistance of the ascending air stream and through the bypass pipe 4 are sent to the dispersing part of the second stage of classification. Fine particles of the material carried by the air flow, rise along the separating part of the column and take It is psheosaditelny with a cyclone where they are separated from the air.

The pouring shelves installed in the separating part, as well as the expansion in its upper part contribute significantly to the increase in the separation efficiency and to the quality improvement of the small product.

In the second and subsequent stages of the classification process occurs similarly. The coarse product is subjected to sequential processing in all columns of the apparatus. Its quality depends on the number of grades in the apparatus.

The adjustment of the separation boundary is made by changing the speed of the air flow in the separating portions of the columns. In the classifier, it is possible to obtain several products that differ from each other in fractional composition. For this, the separating parts of the columns are adjusted to different separation modes. In order to determine the optimal ratio of flow sections of the dispersing and separating parts of the column, laboratory tests were carried out on the model of the classifier in question. The starting material was periclase, chromium oxide and powder for the production of radioceramics. The results of the experiments showed that highly efficient separation can be achieved with the ratio of the flow sections of the separating and dispersing parts of the columns from 2 to 40 with sufficiently stable specific energy consumption. The ratio is determined by the size of the separation boundary size and the physical and mechanical properties of the material.

The guide shelves of the lower ends rest on the dispersing part of the column at the point of their connection with the bypass pipes, while between their upper ends and the walls of the separating part there are gaps for the passage of dust-air mixture. Due to the presence of the guiding shelves, the air flow rising from the dispersing part is diverted from the by-pass nozzle 26,50024

and is discharged into the separation section of the column.

In order to better intermediate the intermediate product, the guide shelves can be perforated before entering 5 it into the overflow pipes. At the same time, part of the air passes through the holes in the shelves and, moving towards the descent of the material flow from the separating part, helps to remove small particles from it.

The narrowing in the lower section of the separating part leads to the fact that ts the air flow rate here is somewhat higher than that required for times / division along a predetermined boundary. As a result, the main part of the fine particles coming from the dispersing part of the column is carried by the air stream to the upper part of the apparatus and, after passing through the cleaning process, is removed to the dust-precipitating cyclones. However, with the right choice

5 values of the constriction, large particles carried by the air flow into the separating part of the column, relatively easily overcome the resistance of the upstream flow and through the transfer inlet get into the dispersing column of the next classification stage.

The optimal value of the restriction (20-40%) was determined by laboratory studies of the model of the proposed apparatus. At smaller values, insufficiently effective separation of fines at each level of classification occurs, which results in fouling of the product with fines, and at large values, large particles carried into the separating part of the column cannot overcome the resistance of the ascending airborne

5 flow, which leads to an increase in the concentration of material in this part of the column, reducing the efficiency of its work and clogging of the small product by large particles.

Test results show

that the separation efficiency at the boundary is less than 100 microns in the proposed classifier 75-80%, and in the known class 5 30-60%. In this case, the number of columns in the proposed device is twice less than in the known.

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Claims (2)

1. PNEUMATIC LOTS-. LONG CLASSIFICATOR, including a number of vertical columns with overflow shelves connected bypass pipes, a device for supplying source material, collections of finished fractions, a pipe for air supply, characterized in that, in order to increase the separation efficiency due to the intensification of the dispersion of the material while stabilizing specific energy consumption, the classifier is equipped with perforated guide shelves _> each column is made of dispersing and separating parts of different passage sections, input the end of the bypass pipe is connected to the separating part in the place of its interfacing with the dispersing part, and the output end to the dispersing part of the next column, while the perforated guide shelf 'is installed in the place of interfacing of the separating and dispersing parts ·. § each column from the side of the bypass pipe and with a gap relative to the opposite wall of the column. - 2. The classifier according to claim 1, about t l c-V, characterized in that the passage section of the dispersing part of the column is 2-40 times less than the separating one. 1 265 002 A