RU2172650C1 - Screen-concentrator - Google Patents

Abstract

FIELD: concentration of minerals; extraction of diamonds from diamond-containing materials. SUBSTANCE: screen - concentrator includes box on bearing frame with screening surface, shock absorber and vibration exciter. Concentrated member made in form of sieve mounted on screening surface on side of unloading edge of screen is secured to side walls of box by means of transversal and longitudinal plates which are fastened together; wavy member located under each transversal plate has passages running from upper cavities of sieve to wavy member zone; upper convex part of each wavy member gets in contact with respective transversal plate of sieve along its lower edge; it is provided with vertical fins welded to inner wavy surfaces and fitted with mating slots for relative fastening of wavy member; transversal plates of sieve are inclined to loading side of screen - concentrator. EFFECT: enhanced efficiency of classifying minerals. 2 dwg

Description

 The invention relates to the field of mineral processing, and in particular to apparatus for gravity processing, and can be used to extract diamonds from diamond-containing materials.

 Known vibration concentrator, including a frame, a concentration element, springs, vibrator, thresholds, gratings, pockets with holes for the output of gravity concentrate [1].

 The disadvantage of the vibration concentrator [1] is connected with the absence of structural elements in it, which make it possible to concentrate and remove mineral grains of increased density uniformly over its entire working area, and not only discretely through pockets with holes.

 The closest in technical essence and the achieved result is a vibrating screen, including a box mounted on a support frame with a sowing surface, shock absorbers and vibration exciter [2].

 The disadvantage of this device is the lack of the necessary structural elements in it, which allow to continuously concentrate and remove mineral grains of high density into a separate product.

 The aim of the invention is to increase the efficiency of classification and gravitational enrichment of minerals by improving the conditions for the separation of mineral mixtures and continuous vibrodynamic removal of fractions of high density in a separate product.

 This goal is achieved by the fact that in the screen, including a box mounted on a supporting frame with a sowing surface, shock absorbers, a vibration exciter, a concentration element mounted on the side walls of the screen mounted on the sowing surface mounted on the side of the screen, made in the form of a sieve with transverse mutually fastened to each other and longitudinal plates and with wavy elements located under each of the transverse plates having slotted passages between the upper cavities of the sieve into the e wave-like elements, with each wave-shaped element in its upper convex part in contact with the corresponding transverse sieve plate along its lower edge and has vertical ribs welded to the internal wave-like surfaces with reciprocal grooves for mutual fastening of the wave-like elements to each other, while the transverse sieve plates are inclined into the loading side.

 When creating the invention, the authors proceeded from the following.

 During vibrations of a layer of diamond-containing material, diamond crystals having a high density and at the same time a significantly lower coefficient of friction with respect to gangue minerals tend to occupy the lowest level in this layer. The necessary conditions for such vibrations of the material layer are created in screening operations. Therefore, it is advisable to additionally create conditions for the concentration and output of diamonds into a separate product on the sowing surface of the vibrating screen. This can be achieved if on the sowing surface of the screen [2] to introduce structural elements that will provide such conditions. In particular, it is rational to install a concentration element fixed to the side walls of the box from the side of the discharge edge of the screen, which is advisable to make it in the form of a sieve with transverse and longitudinal plates mutually fastened to each other and with wavy elements located under each of the transverse plates having slotted passages from the upper interlattice cavities into the area under the wave-like elements. At the same time, each wave-like element must be allowed to touch its corresponding convex part with the corresponding transverse sieve plate along its lower edge. For mutual fastening of the wave-like elements to each other, it is advisable to weld vertical ribs with mating grooves into the internal wave-like surfaces, into which the wave-like elements will be inserted with their edges. It is advisable to tilt the transverse plates of the sieve in this case to the loading side of the screening hub.

 The above conditions for the concentration of the useful component are acceptable not only in relation to diamond-containing materials, but also to many other types of mineral raw materials. Especially when the density of the mineral grains of the useful component is much higher than the density of the grains of waste rock, for example, in the enrichment of gold-bearing ores and sands, in the enrichment of rare-metal raw materials, tin and tungsten ores and many other types of raw materials similar to them.

 The invention is illustrated in the drawing, where in FIG. 1 shows a general view of a screening hub; FIG. 2 is a plan view of a hub concentrator showing details of its concentration element.

 The screening hub includes a box 1 with a sowing surface 2, movably fixed by means of shock absorbers 3 on a supporting frame 4 and designed to create the necessary vibrations of the working body, namely the box 1 with a sowing surface 2, and a vibration exciter 5. In order to increase the efficiency of classification and gravitational enrichment of the processed material on the sowing surface 2 from the side of the discharge edge of the screen is mounted a concentration element 6 firmly fixed to the side walls of the box 1, made in the form of a sieve 7 with by transverse and longitudinal plates 8 and 9, respectively fastened to each other and with wave-shaped elements 10 located under each of the transverse plates 8, having slotted passageways 11 from the upper cavities of the sieve 7 into the area under the wave-like elements 10. Each wave-like element 10 is allowed to be tightly pressed with its upper convex part to the corresponding transverse plate 8 along its lower edge, which allows, on the one hand, to firmly press each wave-like by means of transverse plates 8 th element 10 to the sowing surface 2 and give the necessary rigidity and vibrational performance to the concentration element 6, on the other hand, to ensure the formation of its unit working cells 12. This is also facilitated by the mutual fastening of the wave-like elements 10 to each other by means of vertical ribs welded to the internal wave-like surfaces of these elements 13 with mating grooves 14 into which the wave-like elements 10 are mutually inserted by their edges 15 and 16. For better retention of the mineral grains of the useful compo the tape in a single working cell 12 of the concentration element 6, the transverse plates 8 are inclined to the discharge side of the screen-hub. In order to remove fractions of increased density from the apparatus into a separate product, special receiving chutes can be installed both under each working cell 12 and under a group of such cells in a screening or screening unit of a screening concentrator.

 The roar hub works as follows.

 Pulp or dehydrated material containing diamonds or solid particles of various sizes and densities is fed to the sowing surface 2 of a working screen concentrator, moving along which the material is distributed evenly over the entire width of the screen and sieve and the fine particles are eliminated from it. The material on the sieve can be irrigated with water for better sieving. Next, the vibrating layer of material enters the concentration element 6, where it is separated by density. Diamonds and heavier mineral grains occupy the lowest position in the vibrating layer and then accumulate in each unit working cell 12 on the concave part of the wave-like element 10. As diamonds and heavy mineral grains accumulate in the working cell 12, they enter the edge 15 of the wave-like element 10 into slotted passages 11 and when filling the working cell 12 to the edge 16 go into the area under the wave-like elements. Then, passing through the cells 12 of the sowing surface 2 and the intake chute, they are unloaded from the apparatus in the form of a separate finished product. Light minerals of waste rock, occupying the highest position in the vibrating layer of the material, move with it to the discharge edge of the screening hub and are discharged from the apparatus in the form of a tail product.

 The concentration process is adjusted and regulated by changing the frequency and amplitude of vibration of the box 1 with the sowing surface 2 and the concentration element 6, the size and amount of perforation of the sowing surface 2 and the technological load of the material to be enriched, as well as the amount of water supplied for irrigation.

 Concentration elements 6 can be installed both on single- and double-screen screens, and on multi-screen. Each concentrate product may have its own intake chute.

 Thus, the proposed technical solution in comparison with the prototype will allow, due to improved conditions for the separation of mineral mixtures and continuous vibrodynamic removal of fractions of high density in a separate product, to increase the efficiency of classification and gravitational enrichment of minerals.

Sources of information
1. O. B. Klebanov, L. Ya Schubov, N.K. Shcheglova. - Handbook of a technologist for the enrichment of non-ferrous metal ores. - M.: Nedra, 1974, p. 203, 204.

 2. Handbook of ore dressing. Preparatory processes.-M.: Nedra, 1982, p. 35-52, ed. O.S. Bogdanova is a prototype.

Claims (1)

 A screen-hub, including a box mounted on a supporting frame with a sowing surface, shock absorbers, a vibration exciter, characterized in that a concentrated element mounted on the side walls of the screen is mounted on the sowing surface on the side of the screen, made in the form of a sieve with transverse and mutually fastened to each other longitudinal plates and wavy elements located under each of the transverse plates having slotted passages from each other from the upper cavities of the sieve into the area under the waves shaped elements, each wave-like element with its upper convex part in contact with the corresponding transverse sieve plate along its lower edge and has vertical ribs welded to the internal wave-like surfaces with reciprocal grooves for mutual fastening of the wave-like elements to each other, while the transverse sieve plates are inclined in the discharge side .

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