RU2024317C1 - Diaphragm jig - Google Patents

Abstract

FIELD: enrichment of mineral resources. SUBSTANCE: transition chamber 4 is located inside settling vessel 1 under riddle 2. Chamber 4 is connected with movable cone through diaphragm 6. There is diffuser 5 in chamber 4. Diffuser 5 is formed by inclined plates which are parallel to walls of the chamber and connected by V-shaped members 10. Angle of slope of members 10 is 10-40 deg. less than angle of slope of the plates. As a result, intensity of pulsations may be distributed uniformly along the surface of the riddle. EFFECT: improved efficiency. 2 dwg, 1 tbl

Description

 The invention relates to the enrichment of minerals, in particular to apparatus for gravitational enrichment - diaphragm jigging machines.

 Known diaphragm jigging machines in which water pulsations are created by moving cones located under the sieve [1]. The ore fed to the sieve, under the action of pulsations of water, is stratified into layers with different densities. The disadvantage of this jigging machine is the uneven distribution of the intensity of the pulsations over the surface of the sieve. This is due to the fact that the maximum area of the moving cone - the area of its base - is 39% of the area of the sieve. Therefore, in the center of the sieve, directly above the moving cone, the intensity of the pulsations is 20% higher than at the walls of the sieve, and 30% more than at the corners of it. This leads to clogging of the sieve, weakening and termination of pulsations in the corners and at the walls of the jigging chamber. The unevenness of the pulsations also leads to the movement of grains above the sieve due to the removal of small grains of heavy fractions from the lower layers to the upper ones in the central part of the sieve. This leads to a violation of stratification, deterioration in the quality of the concentrate, a decrease in its yield and extraction of useful components into it.

 The closest in technical essence to the proposed one is a diaphragm jigging machine, in which, to reduce the unevenness of ripples along the surface of the sieve of the jigging chamber, the sublattice frame is made in the form of diffuser mesh gratings [2]. The disadvantage of this device is the inability to effectively equalize the intensity of the ripple above the gratings. This is due to the fact that the unevenness of the pulsations above the sieve is not eliminated: the speed of the vertical flow of water over the cone is greater than in the rest of the sieve. A honeycomb diffuser, uniformly located above the sieve, creates the same resistance to the vertical flow of water over the entire surface of the sieve, and the uneven distribution of the velocity of this stream, suitable from below the sieve, is not eliminated. The honeycomb diffuser creates a great resistance to flow, since its flow area is much smaller than the area of the sieve. This results in a loss of energy requiring amplification of the drive. A slight equalization of the flow velocity due to the hydraulic resistance of the mesh lattice leaves the unevenness of the pulsations in the center, at the edges and corners of the chamber almost the same.

 Such a diffuser honeycomb lattice can have a significant impact on the uniform distribution of pulsations over the surface of the sieve only with a uniform distribution of the velocity of the upward flow of water coming to it from below.

 The aim of the invention is to improve the results of jigging in a diaphragm jigging machine with moving cones by equalizing the intensity of the pulsations over the entire surface of the sieve.

 This is achieved by the fact that the diffuser is installed in the transition chamber of the diaphragm jigging machine and is made of inclined plates mounted parallel to the walls of the sublattice chamber, connected by U-shaped elements, inclined to the horizon at an angle of 10-40 degrees less than the angle of inclination of the plates.

 Comparative analysis with the prototype showed that the proposed device is characterized in that the diffuser is installed in the transition chamber, directly above the movable cone, in the area where the vertical flow of water is evenly distributed over the surface of the base of the movable cone. This allows you to cut off part of the water flow and distribute it on the surface of the central part of the sieve. In this case, part of the water flow, flowing around the diffuser from the outside, is directed through the gap between the machines of the transition chamber and the diffuser to the walls and corners of the depositing sieve. This distribution of flows using the proposed device allows you to evenly distribute the vertical pulsations of water to its approach to the sieve and, therefore, to equalize the amplitude of the pulsations over the surface of the sieve. The diffuser, streamlined by the external and internal water flows, has practically no resistance, since it does not block the vertical flow of water. This leads to a sharp reduction in energy costs and drive power.

 The connection of the plates forming the diffuser, U-shaped elements, such as half pipes, allows you to form a stream of water and direct it to the corners of the jigging chamber.

The angle of inclination of U-shaped elements 10-40 ^of (to the horizontal) is less than the angle of inclination of the plates allows for optimal distribution of flows directed to the corners of the jig chamber.

 In FIG. 1 shows the proposed device, a cross section; in FIG. 2 is a section along AA in FIG.

 The proposed diaphragm jigging machine comprises a jigging chamber 1, in which a sieve 2 and an under-sieve frame 3 are placed, a transition chamber 4 with a diffuser 5, a movable cone 7 with an unloading device 8. The diffuser 5 located above the movable cone 7 in the transition chamber 4 is mounted by brackets 9 to the walls of this camera. The walls forming the diffuser 5 are connected by elements 10 having a U-shaped cross section and a curved shape. The movable cone is connected by elastic cuffs 6 with the camera 4.

 The device operates as follows. The movable cone 7 is driven in a reciprocating motion in the vertical direction. During the upward stroke, the movable cone displaces the water and creates an upward flow of water in the chamber 4. This flow by the diffuser 5 is divided into two parts: internal and external. The internal part of the flow, passing through the diffuser, is distributed over a large area, and the external flow flowing around the diffuser to a smaller area of the sieve chamber 1. This helps to equalize the pulsations over the entire surface of the sieve and prevents mixing of the material inside the deposit chamber. The amplitude of the pulsations over the entire surface of the sieve, including in the corners of the chamber, is almost the same, differing by no more than 3%. This completely eliminates the clogging of the sieve at the walls and in the corners and in the corners of chamber 1, mixing of the supra-bed layer, removal of small grains of heavy ore fractions, for example, gold-containing sulfides, in the center of the chamber and their removal into tails.

 With a decrease in the angle of inclination of the U-shaped elements compared to the inclination of the walls of the diffuser by 0-10 ° (towards the horizon), the ripple uniformity does not improve, from 10 to 40 ° there is a uniform distribution of ripples, more than 40 ° - again an uneven distribution of ripples due to an increase in ripple in the corners cameras.

 With an optimal distribution of pulsations over the surface of the sieve, depositing results are improved.

 The results of the deposition of crushed polymetallic ore in a diaphragm depositing machine before and after installation of the proposed device are presented in the table.

 From the data of the table it follows that the extraction of all sulfides, especially gold-bearing ones, is increasing. At the same time, richer sulfide grains fall into the concentrate, as evidenced by the increased content of metals in the concentrate.

The enrichment efficiency for gold (according to Luikents) is increasing from 27.6 to 35.2%. The consumption of sublattice water decreases from 0.232 to 0.140 m ³ / t. The specific productivity of the jigging machine is increased by 8.76%.

Claims (1)

Diaphragm jigging machine, including a jigging chamber with a sieve and an undergrate frame, an undergrate movable cone connected to a jigging chamber and a moving cone, a transition chamber with inclined walls, a diffuser located under the frame, characterized in that, in order to improve the jigging results by uniformly distributing the pulsations over the surface of the sieve, the diffuser is installed in the transition chamber and is made of inclined plates mounted parallel to the walls of the sublattice chamber, connected by V-shaped elements, inclined to the horizon at an angle of 10 - 40 ^o less than the angle of inclination of the plates.

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