RU20261U1 - INSTALLATION OF HYDROCLASSIFICATION OF GRAIN MATERIALS - Google Patents

Abstract

Installation of hydroclassification of granular materials, including a hydraulic screen with nozzles for inputting the initial slurry, removing gravel and draining the working slurry into a hydraulic classifier, consisting of several sections, each of which is made of a classification chamber with inclined plate packages orthogonally installed in it and equipped with nozzles for entering the working slurry, feed washing water, the release of the condensed product classification through the thickener and the withdrawal of clarified pulp, characterized in that the hydraulic screen and sections guide of the classifier are mounted on the frame in series in the form of a descending cascade with a decrease in the level of the working slurry in each of them relative to each other, with the discharge pipe of the working slurry of the hydraulic screen connected to the input pipe of the working slurry of the first section, the output pipes of the clarified slurry of each previous section are connected by channels to the input pipes of the working hydraulic mixtures of each subsequent section, and flushing water supply pipes of each section are made in the form of collectors connected to a frame mounted idroakkumulyatorom.

Description

2000116540,

HYDRAULIC INSTALLATION 1 ASSIFICATION OF GRAIN MATERIALS

The invention relates to equipment for the classification and enrichment of mineral raw materials and can be used in the processing of minerals and industrial wastes in the industry of ore and non-metallic materials.

A known hydraulic screen, including a cylindrical-conical body with nozzles for inputting the initial slurry and output of screening products, in the inner cavity of which there is a conical sieve that provides the output of a large gravel fraction and the output of small screening products for use as a subsequent working slurry (see patent. RF P2134619 , CL B 07 1/06, 1/08, BI, 1999).

The disadvantage of this technical solution is the lack of the possibility of further classification of small screening products.

A known section of the hydroclassifier, including a housing with nozzles for entering the working fluid mixture, supplying washing water, discharging the condensed product and removing clarified pulp, the classification of which is equipped with inclined plate packs (see RF patent No. 2134614, class B 03 V 5/62, BI, 1999).

A disadvantage of the known technical solution is the narrow scope of its use, limited to the release of only one classification product.

A known slurry thickener comprising a hopper with an inlet pipe of a hydroclassification product and a locking device of the thickening chamber (see RF patent, CL 01.D 21/00, 03 V 5/00, 07 V 1/00, BI mQ, 1999 )., that to the present invention is an enrichment unit, including a conical screen with a nozzle for supplying a hydraulic mixture, a nozzle for removing gravel and a collector of sandy fraction, with which a housing is made using a drain pipe made of two classification pipes arranged with a drain pipe cameras with tilt sand plates with devices for unloading sand and dividing tubes for water supply, the classification chambers being located one above the other, the inclined plates of the lower chamber are perpendicular to the plates of the upper chamber, and the sand accumulators are made with a regulating gate; The disadvantage of this technical solution is the limited technological capabilities in the range of production of classification products and the low quality of the enriched material. The purpose of the proposed technical solution is the expansion of technological capabilities by increasing the output range of the classes of the finished product and improving the quality of their production due to the effective separation of material particles by their hydraulic fineness. This goal is achieved due to the fact that the installation of hydroclassification of granular materials, including a hydraulic screen with nozzles for inputting the initial hydraulic mixture, drainage of gravel and discharge of the working hydraulic mixture into a hydraulic classifier, consisting of several sections, of which are made of a classification chamber with inclined plate packages orthogonally mounted in it and equipped with nozzles for entering the working fluid mixture, supplying .washing water, discharging the condensed product through the thickener, and discharging the clarified pulp, according to the invention the idler screen and hydroclassifier sections are mounted on the frame sequentially in the form of a descending cascade with a decrease in the level of the working slurry in each of them relative to each other, and the discharge pipe of the working slurry of the hydraulic screen is connected to the input pipe of the working slurry of the first section, the output pipes of the clarified pulp of each previous section are connected by channels with the inlet ports for the working fluid mixture of each subsequent section, and the V nozzles for supplying the washing water of each section are made in the form of collectors connected to mounted on the wound gidroakk- / th //: torus. The presence of a sign of a hydraulic screen and a section of a hydroclassifier are mounted on the frame sequentially in the form of a descending cascade with a decrease in the level of the working slurry in each of them relative to each other, and the discharge pipe of the working hydraulic mixture of the hydraulic screen is connected to the input pipe of the working hydraulic mixture of the first section, the output pipes of the clarified pulp of each previous section are connected channels with branch pipes for the input of the working slurry of each subsequent section allows you to expand the technological capabilities of the installation of hydroclassification tion of granular materials. This is achieved due to the fact that the process of hydroclassification of the material is carried out due to the gravity flow of the slurry stream from one tank to another, which occurs when the level of the slurry in the previous tank is higher in height compared to the next. Thus, in a hydraulic screen, the initial slurry is divided into gravel, which is removed from the system along the outer surface of the sieve, made in the form of a bauxite sieve, with minimal losses of process water, and the sublattice product from the granular fraction with water penetrating together with the process water through the slots of the bobbin screen in the body of the hydraulic screen a working hydraulic mixture of a certain height, the level of which is higher than the level of the inlet in the first section of the hydroclassifier. Therefore, due to the difference in height, the working hydraulic mixture flows by gravity into the first section and fills it as a communicating vessel, rising in it to a certain height, namely, to the height of the drain window of the first section. Due to the difference in altitude of these levels, the working hydraulic mixture rises up at a certain speed. This rate of gravity lifting of water in the first section is less than the deposition rate of large particles of material, therefore, large particles are deposited in the first section, and lighter particles move upward together with a gravity flow, which, except for precipitated large particles, is a clarified pulp in the technological water, as well as medium, light and lightest particles of the material. The clarified pulp is poured through the upper hole of the first section into the drain channel and for the second section of the hydroclassifier is already a working hydraulic mixture, but without large particles of material. This working slurry through its drain channel by gravity pours into the inlet of the second section, the level of which is lower than the level of the drain of the first section. Therefore, due to the difference in height, the clarified working hydraulic mixture enters the second section, fills it as a communicating vessel and is poured through the drain hole into the drain channel for overflow into the third section. Since the rise rate of clarified pulp in the second section is less than the deposition rate of medium-sized particles, the latter precipitate in the second section, and the lightest and lightest particles overflow into the third section, the level of which is lower than the level of the second section. Due to the difference in levels in the sections, the hydroclassification process takes place in subsequent sections until the particles of the working slurry completely settle in the next section, and the clarified pulp with waste in the form of the clay fraction is not removed from the system and dumped into the sump for subsequent cleaning and use for water circulation. Thus, the descending cascade of sections of the hydroclassifier with a decrease in the level of the working fluid mixture allows as many classes of granular material as the sections will be installed on the frame in accordance with the hydraulic particle size of the material. The presence of the sign of the flushing water supply pipe for each section is made in the form of collectors connected to a frame G mounted on the frame G (a hydraulic accumulator makes it possible to increase the efficiency of the hydroclassification process and the quality of the finished classes of finished products of granular materials. This is achieved due to the fact that during the gravity overflow of the working hydraulic mixture from one sections to another in each of the sections first precipitate large particles, then

medium-sized particles, then small and tiny particles of granular material. This is the so-called, natural hydroclassification process, which cannot be considered sufficiently effective. The fact is that in the process of natural deposition, for example, of large particles, the mixing of medium-sized particles occurs simultaneously. When particles of medium size are naturally precipitated in the second section, small particles are also captured along with them. Thus, during the natural deposition of particles in each section, clogging of the finished product occurs, reducing its quality. Therefore, the use of flushing water nozzles makes it possible to create an active upward flow in each section, at which the upward flow rate is slightly lower than the material particle deposition rate in this section, i.e., to obtain a clean finished product in accordance with the hydraulic grain size of the deposited material fraction. The location on the frame of the accumulator allows you to create irregularities in the supply of process water to the hydraulic system from the operation of the pump station, and the use of flushing manifolds ensures the required flow of process water to each section regardless of the need for its supply to adjacent sections. These circumstances contribute to increasing the efficiency of the hydroclassification process and obtaining a clean and high-quality product in each section without mixing particles of material deposited in adjacent sections.

Figure 1 presents a General view of the installation of hydroclassification of granular materials; figure 2 is a section along A-B-B-D in figure 1.

The hydroclassification unit for granular materials consists of a hydraulic screen 1 D with the inlet of the initial hydraulic mixture 2, drainage of gravel 3 and the discharge of the working hydraulic mixture 4 in the inlet pipe 5 of the first section of the hydroclassifier b, which is connected through the pipe 7 to the input pipe 9 of the second section of the hydroclassification 10. The last pipe 11 and channel 12 is connected to the inlet pipe 13 of the third section of the hydroclassifier 14, of which clarified

the pulp through the pipe 15 and the drain channel 16 is removed from the hydraulic system. Each of the sections of the hydroclassifier and the hydraulic screen through the racks are mounted on the frame 17, on which the accumulator 18 is located with the supply of process water to it from the pumping station through pipeline 19. From the accumulator through the pipes 20, 21 and 22, water enters the collectors 23, 24 and 26 and through the perforated nozzles 26, 27 and 28 enters each section in the form of ascending flows of wash water. Particles of material deposited in each of the hydroclassification sections are discharged through nozzles 29, 30 and 31 to thickeners 32, 33 and 34 and are discharged into trays 35, 36 and 37 as a finished product.

The operation of the hydroclassification of granular materials is as follows.

When supplying the original slurry through pipe 2 to the hydraulic screen 1, it is divided into gravel, which is discharged through pipe 3, and the working hydraulic mixture. The last pipe 4 and 5 is introduced into the first section of hydroclassification 6, rises in it due to the difference in levels in the hydraulic screen, passes through pipe 7 and channel 8, is introduced through pipe 9 into the second section of hydroclassification, rises in it due to the difference in levels in the first section , is passed through pipe And and channel 12, is introduced through pipe 13 into the third section of hydroclassification 14, rises in it due to the difference in levels in the second section and through pipe 15 and drain channel 16 is removed from the system in the form of spent clay clarified no pulp.

At the same time, process water is supplied through the pipeline 19 from the pump station to the accumulator located on the common frame 17. Water is supplied from the accumulator through the nozzles 20, 21 and 22 to the collectors 23, 24 and 25, which is supplied through the perforated nozzles 26, 27 and 28 in each of sections 6, 10 and 14, forming in them ascending flows of washing water. The speed of the upward flow of water in section 6 is provided such that medium, small and clay particles are carried up, and large particles are deposited in the lower

parts of the section are discharged by pipe: 9 and through the thickener 32 are discharged into the tray 35 in the form of a finished product of a large fraction of granular material. The upward flow velocity in section 10 is provided so that small and clay particles are carried up, and the middle particles are deposited in the lower part of the section, are discharged through the nozzle 30 and, through the thickener 33, are discharged into the tray 36 as a finished product of the middle fraction of granular material. The upward flow velocity in section 14 is provided so that clay (smallest) particles are carried upward, and small particles are deposited in the lower part of the section, discharged through nozzle 31 into the thickener 34 and discharged into the tray 37 as a finished product of a fine fraction of granular material.

Wastes from the production of the smallest clay particles through the nozzle 15 and the drain channel 16 are removed from the system to the sump for subsequent use of the process water by the pumping station for supplying it through the pipe 19 to the accumulator 18.

The technical and economic efficiency of the proposed technical solution consists in creating a mobile installation for the hydroclassification of granular materials, which ensures the expansion of its technological capabilities and an increase in the quality of the finished product in the range of required fractions.

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Claims (1)

Installation of hydroclassification of granular materials, including a hydraulic screen with nozzles for inputting the initial slurry, removal of gravel and draining the working slurry into a hydroclassifier, consisting of several sections, each of which is made of a classification chamber with inclined plate packs orthogonally installed in it and equipped with nozzles for entering the working slurry, supply washing water, the release of the condensed product classification through the thickener and the withdrawal of clarified pulp, characterized in that the hydraulic screen and sections guide of the classifier are mounted on the frame in series in the form of a descending cascade with a decrease in the level of the working slurry in each of them relative to each other, with the discharge pipe of the working slurry of the hydraulic screen connected to the input pipe of the working slurry of the first section, the output pipes of the clarified slurry of each previous section connected by channels to the input pipes of the working hydraulic mixtures of each subsequent section, and flushing water supply nozzles of each section are made in the form of collectors connected to a frame mounted idroakkumulyatorom.