SU1708444A1 - Technique and device used in the concentration of minerals - Google Patents

Abstract

The invention relates to the enrichment of minerals, in particular coal, and m. used in mountain and other industrial areas. The chain of the invention is to improve the quality of separation. The source material (M) serves on the perforated work surface (RP) 1, divided into sections 9 and 10. Under each section 9 and 10 serves air flow. With this, a pulsating air flow is fed into one-UI and 9 through one, and a continuous air flow is sent to adjacent sections 10, the speed of which in each subsequent movement of the fyl section is reduced. The initial M is divided into light and heavy fractions. The light fraction is removed, and the desired output is removed. The device for implementing the method comprises perforated RP 1. Loading device 2 and device 3 for outputting the light fraction located above RP 1, collector 5 with airflow rate regulators 6 and device 7 for creating pulsating air flow. Above RP 1, dividing partitions (F) 8 are parallel to each other along its longitudinal axis. RP 1 is made in the form of an endless belt mounted for rotation. The height P 8 above section 9 is greater than height P 8 above section 10. The height P P above section 10 decreases in the direction of travel M. Device 3 is located above section 10. Air is supplied through RP 1. Coal comes from adaptation 2 to RP 1 The layer of coal limited in height by the P 8 enters section 9. In this case, the separation of M occurs. The coal separated by density from section 9 enters section 10, where additional separation of coal occurs in a continuous air flow, 1 hp f-ly. 2 il. ^^ about ck > & t ^

Description

This invention relates to the enrichment of minerals, particularly coal, and can be used in the mining and other industries.

The purpose of the invention is to improve the quality of separation.

The method is carried out as follows.

The source material is fed to a perforated work surface, divided into sections. Under each section serves air flow. With this, a pulsed air stream is fed into the sections through one, and a continuous air stream into the sections adjacent to them, the speed of which is in each successive course.

the movement of the section material is reduced. The material is divided into light and heavy fractions. The light fraction is removed, and I wish - the output t.

The method of mineral processing is realized in the device.

FIG. 1 shows a general view of the device; in fig. 2 - cross section.

The device includes a perforated working surface 1, a loading device 2 and a device 3 for outputting a light fraction located above the working surface 1. a collector for supplying air flow 4 in section 5 with air flow rate regulators 6 and devices 7 for creating a pulsating air flow and dividing walls 8, located parallel to each other above the working surface 1 along its longitudinal axis. The work surface 1 is made in the form of an endless belt mounted for rotation. The height of the partitions 8 under sections 9 with a pulsating air flow is greater than the height of the partitions 8 above the sections Yus with a continuous air flow. The height of the partitions 8 above the sections 10 decreases as the material moves.

The device 3 is located above the sections 10. The thickness of the source material is controlled by the valve 11. The working surface 1, made in the form of an endless belt, is mounted on the drive 12 and tension 13 drums. The device 3 is made with receiving chutes 14. In front of the drive 12, the drum above the partitions 8 has a height-adjustable gate 15. The drive drum 12 is connected to the electric motor via a gearbox and a speed variator that allows adjusting the enrichment time and the separator performance. The separator is covered with a sealing umbrella 16 connected to the suction system.

The device works as follows.

When the voltage is applied, the drive drum 12 is turned on and air is supplied from the discharge chamber to the working surface 1 through its perforation. At the same time, the air speed is regulated depending on the parameters set for the separation of coal. The coal from the device 2 enters the work surface 1, while the bed thickness is regulated by the valve 11. The coal layer, limited in height by the partitions 8, enters section 9 with a pulsating air flow. When this occurs, the separation of the bulk material into layers of different density; The light fractions are transferred to the upper layer, and the lower layer, located on the working surface 1. The transition is from the heavy fractions. Partly lightly concentrated in the intermediate layer.

and the heavy fractions that in this zone do not have time to move to the corresponding layers. Partitions 8 prevent material from moving across the width of the working surface.

Separated in density coal from section 9 enters section 10c with a continuous air flow, in which additional separation of coal occurs. Here, the light fraction is removed by fixture 3, which enters chute 14. Further coal enrichment is repeated in the next pair of sections 9 and 10. The amount of the heavy fraction is adjusted in height by the gate 15. The dust is collected by an aspiration system.

Formula of invention

1. The method of enrichment of minerals, including the supply of material to

perforated work surface divided into sections, air flow for each section, separation of ma-. lightweight and heavy fractions, removal of the light fraction and extraction of the heavy fraction.

characterized in that. in order to improve the quality of separation, pulsed air flow is supplied to the sections through one section, and continuous air flow to the sections adjacent to them, speed

which in each subsequent in the course of the movement of the material section decreases.

2. A device for mineral processing, including a perforated working surface,

a device and a device for outputting a light fraction, located above the working surface, and a manifold for supplying air flow to sections with air flow rate regulators, which is so heavy. that, in order to improve the quality of separation, the device is equipped with devices for creating a pulsating air flow, installed in the manifold for supplying the air flow, and dividing partitions parallel to each other above the working surface along its longitudinal axis, while the working surface is made in the form of an infinite ribbons installed with the possibility of rotation, and the height of the dividing walls above the sections with pulsating air flow is greater than the height of the dividing walls over sections with continuous air flow, the height of the dividing

Claims (2)

Claim 1. A method of mineral processing, including feeding material onto a perforated work surface divided into sections, supplying air flow under each section, separating the material into light and heavy fractions, removing the light fraction and outputting the heavy fraction, characterized in that, in order to improve quality separation, in the section through one serves a pulsating air flow, and in adjacent sections of a continuous air stream, the speed of which in each subsequent section of the material is reduced. 2. A device for mineral processing, including a perforated working surface, a loading device and a device for outputting light fractions located above the working surface, and a collector for supplying air flow to the section with air flow speed controllers, characterized in that. that, in order to improve the quality of separation, the device is equipped with devices for creating a pulsating air flow installed in the manifold for supplying air flow, and dividing walls parallel to each other above the working surface along its longitudinal axis, while the working surface is made in the form of an endless ribbon installed with the possibility of rotation, and the height of the partition walls above the sections with a pulsating air flow greater than the height of the partition walls by d sections with a continuous air flow, and the height of the separation walls above the sections with a continuous air stream decreases in the direction of movement of the material, and the device for outputting the light fraction is located above the sections with a continuous air stream. Yuig. 2