RU2320418C1 - Device for classifying solid particles - Google Patents

Abstract

FIELD: separation solids from solids.

SUBSTANCE: device comprises cylindrical tank with vertical longitudinal axis, means for setting the pulp in rotation around the longitudinal axis of the tank made of branch pipes that are arranged tangentially with respect to the housing and used for supplying pulp, and blade swirler made of an unmovable screw mounted coaxially to the longitudinal axis of the tank. The housing of the tank is sectional. Each section excluding bottom and top section is made of a shell whose bottom end is provided with a ring chute. The inner wall of the chute is parallel to the inner surface of the envelope and is mounted with a spaced relation to the envelope. The outer wall is mounted with a spaced relation to the outer side of the shell. The face of the shell is mounted with a spaced relation to the bottom of the chute, and space of the chute is connected with the tank for receiving particles.

EFFECT: enhanced quality of classification.

5 cl, 4 dwg

Description

The invention relates to the field of engineering and technology for the extraction of particles from disperse systems (suspensions, colloidal solutions, suspensions) and can be used in the processing of industrial deposits - epic heaps of concentration plants, with a particle size of solid particles less than 2 mm

A device is known for separating solid particles in a pulp with different hydraulic sizes, including a cylindrical body with a flat bottom, a pulp receiving chamber located along the axis of the body, devices for outputting heavy and light fractions, characterized in that the cylindrical body with a flat bottom is divided into several chambers by cylindrical partitions , in the bottoms of which are water nozzles that supply water under pressure parallel to the bottom, and the direction of movement of water flows in the conjugate chambers is false, the removal of tailings is carried out through the upper edge of the last circular chamber into the tail housing with an inclined bottom, the device for selecting heavy fractions is made in the form of slots located on the bottoms of the chambers (see US Pat. RF No. 2045351, V03B 5/32, 1995) .

The device is a combination of the signs of a continuous centrifugal concentrator (a fixed cylinder with a flat bottom and spiral thread) and a cyclone-type centrifugal concentrator (tangential flow of a water stream under pressure).

However, this device does not fully capture particles with a particle size of less than 0.041 mm, which leads to irretrievable losses of valuable components, are inefficient. Gravity concentrates obtained on the above devices do not differ in high content of valuable components.

There is also known a device for separating solid particles with different hydraulic sizes in a pulp, containing a cylindrical tank with a vertical longitudinal axis, a means of imparting rotational movement to the pulp around the longitudinal axis of the tank (see US Pat. RF No. 2039607, B03B 5/32, 1995).

The disadvantage of this device is the insufficient quality of separation of particles of solid material, especially when the densities of the tails and the useful component, not differing in high contrast.

The problem to which the invention is directed, is to improve the quality of separation of particles of solid material, especially at densities of the tails and useful component, not differing in high contrast.

The technical result achieved in solving the problem is expressed in providing the possibility of separating particles of solid material into a significant number of fractions in which the contrast of the densities of the tails and the useful component ensures their effective separation by screening. In addition, the design of the device is simplified and the energy consumption of the process of separation of the material by hydraulic size is reduced.

The problem is solved in that the device for separating solid particles in the pulp with different hydraulic sizes, containing a cylindrical tank with a vertical longitudinal axis, means for imparting rotational movement of the pulp around the longitudinal axis of the tank, characterized in that the means for imparting rotational movement of the pulp around the longitudinal axis of the tank in the form of nozzles tangential with respect to the tank body for the lower pulp supply and the blade swirler, made in the form of a screw, secured stationary, coaxial to the longitudinal axis of the tank, while the tank body is made up of sections, each section, except the lowest and highest, is made in the form of a shell, at the lower end of which an annular groove is fixed, the inner wall of the groove is parallel to the inner surface of the shell, with a gap relative to the latter and up to 0.6 of the height of the section, and the outer wall is placed with a gap relative to the outer surface of the shell, while the end of the shell is placed with a gap relative to the bottom of the gutter, and The trough cavity is connected to a container for receiving separated particles from it. In addition, the surface of the gutter facing the underlying section is provided with an annular groove made with the possibility of placing the upper end of the lower section in it. In addition, the inner diameter of the cavity of the annular groove is determined from the expression D _P = D _s -5, mm, where D _P is the internal diameter of the cavity of the annular groove, mm; D _with - the diameter of the cavity of the shell, mm, in addition, the width of the input gap of the gutter is 1.7-5 times less than the width of the gap between the inner wall of the gutter and the surface of the cavity of the shell. In addition, the upper edge of the upper section is provided with a groove provided with means for removing tails. In addition, the longitudinal axis of the nozzles in the horizontal plane is made curved. In addition, the blade swirl is made of composite elements whose length is equal to or a multiple of the height of the section.

A comparative analysis of the features of the claimed solutions with the features of the prototype and analogues indicates the compliance of the claimed solutions with the criterion of "novelty."

The features of the characterizing part of the claims provide a solution to a set of functional tasks.

The signs "... the means of imparting rotational motion to the pulp around the longitudinal axis of the tank are made in the form of nozzles tangential with respect to the tank body for the lower pulp and blade swirler inlet, made in the form of a screw fixed motionless, coaxially to the longitudinal axis of the tank" ensure the formation of a rotational-translational flow in cavity of the tank, providing the application of solids to centrifugal force.

The signs "... while the tank body is made of composite sections" provide the possibility of dividing the material into fractions, the number of which corresponds to the number of sections.

Signs "... each section, except the lowest and upper, is made in the form of a shell, at the lower end of which an annular groove is fixed, the inner wall of the groove is parallel to the inner surface of the shell, placed with a gap relative to the latter and is up to 0.6 of the height of the section, and the outer wall is placed with a gap relative to the outer surface of the shell, while the end face of the shell is placed with a gap relative to the bottom of the gutter, and the cavity of the gutter is connected to a container for receiving separated particles from it, ” and when moving along the tank, the hydraulic fineness of the material taken in the fraction decreases as the pulp moves up.

The features of the second claim provide for the fixation of the sections on top of each other.

The features of the third claim specify the design of the gutter elements.

The features of the fourth claim provide for the removal of tails and liquid fractions in a continuous mode.

The signs of the fifth to sixth claims describe the design features of the blade vortex swirler and elements that ensure swirling the flow of pulp.

The claimed invention is illustrated by drawings, in which are shown: in Fig. 1 is a general diagram of a concentration plant; figure 2 is a longitudinal section of an enrichment device; figure 3 shows a cross section of the device at the level of the receiving nozzles; figure 4 shows a cross section of the gutter.

The drawings show a loading unit 1, supply pipelines 2, a cylindrical tank 3 with a vertical longitudinal axis 4, nozzles 5 tangential to the body of the tank 3, a blade swirler 6, section 7, an annular groove 8, the inner wall 9 of which is placed with a gap 10 relative to the surface 11 cavity shell. In addition, the end face 12 of the shell is shown, placed with a gap 13 relative to the bottom 14 of the groove 8 (for which sections of the bar are fixed on it or cuts are made, not shown). The outer wall 15 of the gutter is placed with a gap relative to the outer surface 16 of the shell, and the cavity of the gutter is connected with a tank 17 for receiving material from it. In addition, the surface of the groove 18 is shown, facing the underlying section 7, provided with an annular groove 19, the upper edge 20 of the upper section 7, equipped with a groove 21, and means 22 for removing material (tails or useful component). In addition, swirler elements 23 are shown.

The named elements are made of metal and, in addition to those mentioned below, are made in a known manner and provide a solution to known problems.

The loading unit 1 is made in the form of a tank equipped with pipelines for supplying water, means for loading solid material, for example, a sand pump, and mixers of known design (not shown). The claimed device is intended for the processing of sands and epelic fractions from the dumps of processing plants with a particle size of less than 2 mm, a density of more than 3 g / cm ³ . The loading unit 1 provides the preparation of pulp with a ratio of Solid: Liquid (T: W) 20:80 or 30:70. The loading unit 1 is carried out 25-40 m above the cylindrical tank 3 (depending on the dimensions - the length and diameter of the latter). The supply pipelines 2 are made of pipes with a diameter of about 100 mm and connect the loading unit 1 to the nozzles 5. The longitudinal axis of the nozzles 5 in the horizontal plane can be made curved, which provides additional “twisting” of the pulp jets when they are introduced into the cavity of the tank. The blade swirl 6 is made in the form of a screw, the direction of "twist" of which corresponds to the direction of the pulp through the tangential nozzles 5. The screw is fixed motionless, coaxially with the longitudinal axis 4 of the tank 3. In addition, the blade swirl is made of composite elements 23, the length of which is equal to or a multiple of the height sections 7. Sections 7, except the lowest and upper, do not differ from each other and are made in the form of a shell, at the lower end of which an annular groove 8 is fixed, the inner wall 9 of which is placed with a gap of 10 relative about the surface 11 of the cavity of the shell, while the end face 12 of the shell is placed with a gap 13 relative to the bottom 14 of the groove 8, the outer wall 15 of which is placed with a gap relative to the outer surface 16 of the shell. In addition, the inner wall 9 of the groove 8 is parallel to the surface 11 of the cavity of the shell and is up to 0.6 from the height of the section 7, while the inner diameter of the cavity of the annular groove 8 is determined from the expression D _P = D _s -5, mm, where D _P is the inner the diameter of the cavity of the annular groove, mm; D _with - the diameter of the cavity of the shell, mm, in addition, the width of the inlet portion of the gap 10 is 1.7-5 times less than the gap on the rest of the length of the shell (which is up to 5 mm). The size of the gap 13 and the input section of the gap 10 in the lower sections is about 3 mm, and in the upper - 1 mm. Section diameter 700-1000 mm, height up to 1000 mm. In addition, the upper edge 20 of the upper section 7 is provided with an additional groove 21. Below the groove 8 of the lower section 7 there is a cylindrical body provided with a bottom (into which the nozzles 5 are “embedded”). The total height of the tank, made up of sections 7, is up to 5 m. The cavities of the troughs 5 are equipped with means for removing tails, for example, inclined pipelines cut into the bottom of the trough, and can be sealed with ring covers (not shown) from above. The drawings do not show the adjustment valves on the installation elements.

The claimed device operates as follows.

The pulp with a ratio of T: L = 20: 80 flows by gravity from the loading unit 1 through the supply piping 2 to the nozzles 5 of the cylindrical tank 3. The tangential pulp input, which is consistent across all nozzles (directed along the perimeter of the reservoir cavity), ensures twisting of the pulp volume (gives it rotational-translational upward movement). An additional twisting effect provides the blade swirler 6.

Rotational motion of the flow provides the application of centrifugal force to the particles of solid material, leading to their radial movement to the walls of the tank (sections 7). Hitting the latter, the particles lose their speed and “flow” along the walls of the sections, falling into the corresponding gaps 10 through their inlet sections (the lower the hydraulic particle size of the particles, the higher they “rise” in the tank). Since in the gaps 10 of the tank only gravitational forces act on the particles, they fall to the bottom of the gutter, "flowing out" through the gap 13 outside the tank body. Then they by gravity or forcibly assigned to the storage location of this fraction.

Claims (6)

1. A device for separating in the pulp of solid particles with different hydraulic sizes, containing a cylindrical tank with a vertical longitudinal axis, a means of imparting rotational movement of the pulp around the longitudinal axis of the tank, characterized in that the means of imparting rotational movement of the pulp around the longitudinal axis of the tank is made in the form of tangential relative to the body of the reservoir pipe for the lower pulp and blade swirler, made in the form of a screw, fixed motionless, coaxially extended axis of the tank, while the tank body is made up of sections, each section, except the lowest and highest, is made in the form of a shell, at the lower end of which an annular groove is fixed, the inner wall of the groove is parallel to the inner surface of the shell, placed with a gap relative to the last and up to 0.6 from the height of the section, and the outer wall is placed with a gap relative to the outer surface of the shell, while the end of the shell is placed with a gap relative to the bottom of the gutter, and the cavity of the gutter is connected with the tank To receive therefrom the separated particles. 2. The device according to claim 1, characterized in that the surface of the trough facing the underlying section is provided with an annular groove configured to accommodate the upper end of the lower section. 3. The device according to claim 1, characterized in that the inner diameter of the cavity of the annular groove is determined from the expression D _P = D _s -5, mm, where D _P is the internal diameter of the cavity of the annular groove, mm; D _with - the diameter of the cavity of the shell, mm, in addition, the width of the input gap of the gutter is 1.7-5 times less than the width of the gap between the inner wall of the gutter and the surface of the cavity of the shell. 4. The device according to claim 1, characterized in that the upper edge of the upper section is provided with a groove provided with means for removing tails. 5. The device according to claim 1, characterized in that the longitudinal axis of the nozzles in the horizontal plane is made curved. 6. The device according to claim 1, characterized in that the blade swirler is made of composite elements whose length is equal to or a multiple of the height of the section.

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