RU2168364C2 - Installation for hydraulically sorting granular materials - Google Patents

Abstract

FIELD: concentration, separation, thickening of granular materials in building, chemical, mining industry branches for processing mineral raw materials and production waste materials, particularly in gold mining for concentrating wastes at operation of sluicing apparatuses. SUBSTANCE: installation includes several sorting sections in the form of cylinder-cone vessels arranged one under another. Slit-type hydraulic aggregate with accumulating hopper is mounted over branch pipe for introducing hydraulic mixture to upper section. Accumulation hopper is jointly mounted by means of two telescopic stands on supporting frame. Carrying surface of hydraulic screen has two curvilinear convex screening surfaces. Upper screening surface has T-shaped cross section guides with slits widening towards discharging end and designed for discharging large-size lumps of material in percussion-free mode. Lower surface is placed between upper guides. EFFECT: enhanced operational reliability of installation. 4 dwg

Description

 The invention relates to the field of devices for the enrichment, separation and thickening of granular materials in the construction, chemical and mining industries for the processing of mineral raw materials and industrial wastes and, in particular, in the gold mining sub-sector for the enrichment of waste products of lock industrial devices.

 A known enrichment unit for receiving, enriching and separating gravel and sand mixtures in hydromechanized quarries of non-metallic building materials supplied by suction pumps to a housing made of two consecutive chambers with conical bottoms, inclined plates for introducing hydraulic mixtures, supplying clean water, draining and outputting classification products , a distinctive feature of which is that between the input pipe of the initial slurry and the first classification chamber is installed a conical hydrog rumble with a screening surface for the removal of gravel from the process of sand enrichment / cm. autos N1695983, cl. B 03 B 5/62, BI N 45, 1991 /.

 The disadvantage of this technical solution is the low operational reliability of the unit due to the rapid destruction of the sifting surface of the hydraulic screen under the influence of impacts of large pieces of material, as well as abrasive wear from gravel and sand coming through the hydraulic mixture from the dredger.

 For the classification and enrichment of materials at the enterprises of the gold mining subsector of the mining industry in open pit mining, hydromechanized industrial devices based on fixed locks were widely used. Fixed locks are inclined trays with a width of 0.5-1.5 m and a length of 6-20 m, installed under a slope of 3-15, the bottom of which consists of transverse protrusions and depressions. The feedstock is supplied with bulldozers to the head of the airlock, where it is washed away by a hydraulic monitor, and the resulting slurry enters the airlock, flows downhill. In this case, particles of high density are lowered by gravity to the stencils of the bottom of the airlock and are retained in the depressions, and particles of lower density, together with large pieces of gangue, are carried in suspension and unloaded along with the flow / cm. Kizevalter "Theoretical Foundations of Gravitational Enrichment Processes", M., "Nedra", 1979, p. 244-250 /.

 The main disadvantage of flushing devices based on fixed locks is the low efficiency of their use, since more than 50% of the useful product, which is irretrievably lost in the drain, is wasted. It should be noted that not only large pieces of material, but also small and tiny particles of a useful product, which are extracted without any difficulty by known methods of hydroclassification of granular materials, in particular, on devices based on the use of downward flows of hydraulic mixtures and get into the drain from the airlock, ascending wash water.

 The closest in technical essence and the achieved result to the present invention is a unit for the hydroclassification of materials, including several sections located one below the other, each of which consists of a drain chamber and a cylinder-conical tank, nozzles for introducing classified material, nozzles for outputting condensed products of classification and nozzles for overflowing hydraulic mixtures from overlying drain chamber into the underlying cylindrical-conical tank (see O. Klebanov and others. Reference Technologist enrichment p e-ferrous metals. M., Nedra, pp. 459-460, fig. 104).

 The disadvantage of this technical solution is the low operational reliability due to the fact that when using the installation for working on waste material from the drainage of a floodgate industrial device, large pieces in a slurry stream destroy in a short time the longitudinal slotted grate in the bottom of the hopper-feeder.

 The problem to which the present invention is directed, is to increase the operational reliability of the installation of hydroclassification of granular materials when working on hydraulic mixtures containing coarse fractions and small particles of various densities.

 To solve this problem, the installation of hydroclassification of granular materials, including several classification sections placed on the support frame one below the other, each of which consists of a cylinder-conical tank with hydraulic mixture inlet nozzles, washing water and condensed product outlet, and a drain chamber with overflow pipe for classification products from one section in another, according to the invention, is equipped with a slotted hydro screen with a storage tank mounted above the nozzle for introducing the hydraulic mixture into the upper section ohm, pivotally mounted on telescopic racks of the support frame, and the working surface of the hydraulic screen has a curved convex shape with two screening surfaces, the upper of which is made of T-shaped guides with slots expanding to the discharge end, and the lower surface is made of longitudinal trapezoidal cross-sections and placed between the guides of the upper surface.

 The presence of the sign "it is equipped with a slotted hydro screen with a hopper accumulating hinge mounted pivotally on telescopic racks of the support frame installed above the nozzle for introducing the hydraulic mixture into the upper section" allows expanding the technological capabilities of the hydroclassification of granular materials. This is achieved due to the fact that the use of a slit hydro screen with a lower accumulating slurry hopper allows the primary hydroclassification of the material, during which a large fraction is removed from the process along the surface of the hydro screen and a small fraction in the composition of waste rock and useful product is accumulated in the hopper for subsequent revenues to the hydroclassification system. And since the hydraulic screen together with the accumulating slurry hopper is pivotally mounted on telescopic racks relative to the supporting frame with classifying equipment, its installation relative to the outlet window of the lock industrial device allows you to adjust the height and angle of inclination of the hydraulic screen in such a way as to ensure an unstressed drop of the slurry flow on the receiving surface.

 The presence of the sign "the working surface of the hydraulic screen has a curved convex shape with two screening surfaces" allows to increase the operational reliability of the installation. This is achieved due to the fact that the outflowing slurry stream as a part of large-sized and small particles of material in its free fall from the outlet window of the airlock has a parabolic stream. Therefore, for a shockless flow of the slurry to the surface of the hydraulic screen, the surface shape must also be curved and convex. Moreover, the upper surface of the hydraulic screen is designed to receive and discharge a large fraction of the material, and the lower screening surface performs the functions of the primary classification of small particles of waste rock and a useful product.

 The presence of the sign "the upper screening surface is made in the form of guides of a T-shaped section with slots expanding to the discharge end" allows to increase the operational reliability of the installation. This is achieved due to the fact that the large pieces of material available in the slurry stream during their free fall in the shockless mode or upon impact enter the curved guide plates, slide along them in the water stream and are dumped into the dump. In order for the pieces of rock in the process of moving along the guides not to jam and not impede the movement of subsequent pieces, the gap between these guides in a top view has a wedge-shaped shape, that is, it expands as it approaches the discharge end of the hydraulic screen.

 The presence of the sign "the lower surface is made of longitudinal pins of trapezoidal cross section and placed between the guides of the upper surface" also improves the operational reliability of the installation. This is achieved by the fact that below the level of the horizontal plates of the T-shaped guides in the zones between their walls, a slurry flow in the composition of small particles of waste rock and useful product slides. Since the density of particles of a useful product is higher than that of gangue, they fall to a greater extent through longitudinal gaps than particles of gangue that are carried away by a stream of water to a dump. Due to the fact that the pins in their cross section are trapezoidal with a wider base at the top, the gaps between the pins exclude the possibility of jamming of particles between them and contribute to the active accumulation of rock particles and useful product together with water in a lower storage hopper.

 In FIG. 1 shows a General view of the installation of hydroclassification of granular materials, figure 2 is the same, top view, figure 3 is a section along aa in fig. 1, FIG. 4 is a section along BB in FIG. 1.

 The hydroclassification installation of granular materials consists of a hydraulic screen 1 with an accumulating hopper 2, which is mounted on a supporting frame 7 using two pairs of telescopic racks 3 and 4 with hinges 5 and 6. Several, for example, three classification sections are located below the outlet window of the accumulating hopper . The upper section is connected with its outlet pipe 8 of the hydraulic mixture to the outlet window of the storage hopper and consists of a cylinder-conical tank 9 with a pipe 10 for supplying washing water and a pipe 11 for output of condensed product, as well as a drain chamber 12 with a pipe 13 for overflow of classification products into the middle section. The middle classifying section consists of a pipe 14 for receiving classification products from the upper section, a cylinder-conical section 15, a pipe 16 for supplying washing water, a pipe 17 for outputting the condensed product, and a drain chamber 18 with a pipe 19 for overflow of classification products into the lower section. The lower classification section consists of a nozzle 20 for receiving classification products from the middle section, a cylinder-conical tank 21, a nozzle 22 for supplying washing water, a nozzle 23 for withdrawing the condensed product, and a drain chamber 24 with a nozzle 25 for draining clarified water with clay waste particles. The working surface of the hydraulic screen has a curved convex shape with two screening surfaces, and the upper surface 26 is made in the form of T-section guides with slots widening towards the discharge end, and the lower surface 27 is placed between the guides in the form of longitudinal split screens.

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

 The complete assembly on the supporting frame 7 is delivered to the place of its operation and placed under a slice of the outlet window of the flushing device sluice so that the hydraulic mixture flows onto the bearing surface 26 of the hydraulic screen 1. The necessary adjustment of the height of the bearing surface of the hydraulic screen is carried out by telescopic racks 3 and 4 connected to the screen with hinges 5 and 6. Then, the nozzles 10, 16 and 22 are connected to the process water system with the aim of generating upward flows in the cylinder-conical chambers 9, 15 and 21 with a given orostyu washing and deposition of large, medium and small particles of a certain density. When a washing device is turned on, a useful product is deposited on the stencils of its bottom, and waste consisting of large pieces and particles of various sizes and densities is discharged from the outlet window of the airlock and transferred to the bearing surface of the hydraulic screen 1. In this case, large pieces of material in the slurry stream slide along T -shaped guides of the upper bearing surface 26 and are dumped into the blade. Small pieces of material and suspended particles of waste rock and useful product fall into the water stream through the wedge-shaped slots between the T-shaped guides of the upper bearing surface 26 and enter the lower bearing surface 27, which consists of longitudinal bearing spalls of trapezoidal section. In this case, small pieces of material and the smallest particles of rock are carried away in the water stream and dumped into the dump, and particles of high-density material fall through the slits of the lower bearing surface 27 and together with the water enter the storage hopper 2. The resulting hydraulic mixture without small pieces and with a minimum content of the smallest particles of waste rock from the accumulation tank 2 enters through the pipe 8 into the cylinder-conical tank 9 of the upper section, where it is classified in an upward flow of water in such a way that high density particles that are periodically released through the outlet pipe 11 of the condensed product. Particles of medium size and density, together with light particles and low density, are removed from the cylinder-conical tank 9 by a stream of ascending wash water, freely poured into the drain chamber 12, and through the overflow pipe 13 enter the hydraulic mixture inlet pipe 14 into the middle section. Here, particles of medium size and density are deposited in the cylinder-conical tank 15, which are periodically discharged through the pipe 17. Small particles of small density are carried out by an upward flow of water from the tank 15 into the drain chamber 18 and overflow through the pipe 19 into the pipe 20 of the lower section. Here, small and low density particles are deposited in the cylinder-conical tank 21, which are periodically discharged through the pipe 23. The lightest suspended particles are discharged by an ascending stream of water from the tank 21 into the drain chamber 24 and are gravity dumped into the dump or sent to the water circulation system.

 Thus, the use of a hydroclassification unit for granular materials equipped with a hydraulic screen with a curved convex surface with an upper T-shaped bearing surface with wedge-shaped slots diverging towards the discharge end and with the lower bearing surface in the form of longitudinal bolts allows for unloading pieces of material and capture small particles different densities for the purpose of subsequent classification and obtaining a useful product.

Claims (1)

 Installation of hydroclassification of granular materials, including placing on the support frame one below the other several classification sections, each of which consists of a cylinder-conical tank with nozzles for introducing slurry, washing water and the outlet of condensed product and a drain chamber with a nozzle for overflow of classification products from one section to another, characterized the fact that it is equipped with a slotted hydro screen with a storage hopper mounted above the nozzle for introducing the hydraulic mixture into the upper section, pivotally fixed telescopic racks of the supporting frame, and the working surface of the hydraulic screen has a curved convex shape with two screening surfaces, the upper of which is made in the form of guides of a T-shaped section with slots expanding to the discharge end, and the lower surface is made of longitudinal trapezoidal crosspieces and placed between guides of the upper surface.

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