RU2166371C1 - Hydrocyclone - Google Patents

Abstract

FIELD: mineral concentration; applicable in ore and coal mining and other industries. SUBSTANCE: baffle plates in hydrocyclone are installed on internal surface of discharge branch pipe and made in the form of upper and lower shortened epicycloids relative to inlet of discharge branch pipe and in cross-section perpendicular to hydrocyclone axis. In this case, total height of shortened epicycloid does not exceed two diameters of cylindrical part of discharge branch pipe. Height of lower shortened epicycloid does not exceed one third of diameter of cylindrical part of discharge branch pipe. Immovable circumference of upper shortened epicycloid is equal to diameter of cylindrical part of discharge branch pipe, and that of lower shortened epicycloid is equal to diameter of circumscribed circumference of upper shortened epicycloid. EFFECT: higher efficiency of separation due to additional withdrawal of fine and light particles. 2 dwg

Description

 The invention relates to the field of mineral processing, in particular to the separation of materials by size and density in a centrifugal field, and can be used in mining, coal and ore processing enterprises and other industries.

 Known hydrocyclone containing a cylindrical housing with a supply pipe, a sand nozzle and a drain pipe with gear flexible elements at its lower end, while the gear elements are made in the form of pointed rods or rectangular plates curved in the shape of a propeller (AS USSR N 1047521, B 04 C 5/13, 1982).

 The disadvantage of this device is the low efficiency of the separation of material by size and density, due to the fact that the hydrocyclone with a drain pipe of known design does not provide stable operation of the apparatus. When relatively dense suspensions are separated or a large load on the hydrocyclone occurs, the toothed flexible elements may periodically block the drain port opening. Overlap of the nozzle opening can also occur with a short-term change in the supply pressure and its qualitative and quantitative characteristics due to the intermittent operation of the feed pump.

 The ratio of the diameters of the sand and drain holes (discharge ratio) is the main regulatory parameter during the operation of the hydrocyclone. Changing the discharge ratio significantly affects all performance indicators of hydrocyclones and, above all, the redistribution of sand and drain volumes, as well as the clogging of separation products. Therefore, a periodic change in the diameter of the drain hole, and therefore the discharge ratio, significantly reduces the efficiency of material separation.

 The relatively small wear of the gear elements of the drain pipe, which increases their flexibility, causes large-scale pulsations of the suspension at the inlet to the drain pipe and around the gear elements, which also reduces the efficiency of separation of materials by size and density.

 A hydrocyclone is known, including a cylindrical conical body, a spiral feed pipe, a sand nozzle and a drain pipe equipped with chippers located on its outer surface, made in the form of curved profiles of variable cross section, the convex surface of which is directed to the cylindrical part of the hydrocyclone body (AS USSR N 971469 B 03 B 5/34, 1982).

 The disadvantage of this device is that it does not provide an effective cleaning of the separation products. This is due to the fact that at the entrance to the drain pipe there is a mutual deformation of flows: moving from above on the outer surface of the drain pipe and coming from below from the conical part of the hydrocyclone body. The presence of chippers intensifies the mutual deformation of flows due to the narrowing of the working space in the cylindrical part near the outer wall of the drain pipe. As a result, the effect of various factors is enhanced, the influence of which determines the nature and effectiveness of separation. Among these factors are the mechanical interaction of particles with each other and with the walls of the drain pipe and chippers, the presence in the flows of local irregularities and turbulent vortices, the unevenness of the concentration fields, the formation of conglomerates of particles.

 In addition, the shape of the chippers, made in the form of curved profiles of variable cross section, contributes to a relatively sharp periodic perturbation of the particle flow moving along the cylindrical wall of the body to the sand nozzle of the hydrocyclone, which creates conditions for mixing already separated particles. The small area of the end surfaces of the bumpers does not allow efficiently directing particles close to the boundary size and separation density to the sand nozzle of the hydrocyclone.

 The swirling flow in the cylindrical part of the drain pipe in height from the inlet, not exceeding two diameters of the cylindrical part of the pipe, is a complex flow with a significant radial gradient of static pressure and a continuous character of changing local parameters along the channel cross section. Such a flow contains elements of simpler types — the region of the near-wall flow corresponding to the boundary layer, the near-axis region of the reverse flow, and the zone of circulation flow located between them. A significant part of the thin and light particles, as well as particles close to the boundary size and separation density, can be directed through the near-axial region of the reverse flow from the drain pipe to the sand nozzle of the hydrocyclone. This process adversely affects separation efficiency.

 Thus, the mutual deformation of the flows at the inlet to the drain pipe, the shape of the chippers and the presence of an axial region of the reverse flow in the drain pipe violate the structure of the flows and are sources of additional turbulization, which does not reduce the intensity of mixing of the products of classification and enrichment in the working area of the hydrocyclone and significantly reduces separation efficiency.

 The last of the analogues is taken as a prototype.

 The present invention improves the separation efficiency of the material due to the additional extraction of fine and light particles. In addition, a more perfect structure of suspension flows with a low degree of turbulence increases the productivity and life of the hydrocyclone.

 To achieve the specified technical result in the described hydrocyclone, including a cylinder-conical housing, a supply pipe, a drain pipe with chippers on its surface, a sand nozzle, chippers are installed on the inner surface of the drain pipe and are made in the form of an upper and lower shortened epicycloid relative to the entrance to the drain pipe and into the cross section perpendicular to the axis of the hydrocyclone, the total height of the shortened epicycloid does not exceed two diameters of the cylindrical part of the drain pipe, and the height of the lower a shortened epicycloid does not exceed a third of the diameter of the cylindrical part of the drain pipe, while the fixed circle at the upper shortened epicycloid is equal to the diameter of the cylindrical part of the drain pipe, and at the lower shortened epicycloid, the diameter of the circumscribed circle of the upper shortened epicycloid.

Comparative analysis with the prototype shows that the hallmarks of the invention are:
- installation on the inner surface of the drain pipe of the chippers;
- the implementation of the chippers in the form of upper and lower shortened epicycloids relative to the entrance to the drain pipe and in a section perpendicular to the axis of the hydrocyclone;
- implementation of chippers in the form of shortened epicycloids with a total height not exceeding two diameters of the cylindrical part of the drain pipe;
- the implementation of chippers in the form of a lower shortened epicycloid with a height not exceeding one third of the diameter of the cylindrical part of the drain pipe;
- the implementation of chippers in the form of an upper shortened epicycloid with a fixed circle equal to the diameter of the cylindrical part of the drain pipe;
- the implementation of chippers in the form of a lower shortened epicycloid with a fixed circle equal to the diameter of the circumscribed circle of the upper shortened epicycloid.

 Thus, the claimed technical solution is new.

 Analysis of other technical solutions related to hydrocyclones, does not allow to identify in them the features that distinguish the claimed solution from the prototype, which allows us to conclude that the criterion of "inventive step".

 In the present invention, due to the presence of new distinctive features, there are the following significant differences.

 The installation of fenders on the inner surface of the drain pipe contributes to the attenuation of the swirling flow, which leads to the transformation of local parameters: the axial and total velocities at the periphery decrease, and in the near-axis zone they increase. In this case, the region of the reverse axial movement of the suspension degenerates, which increases the separation efficiency due to the termination of the particle flow from the drain pipe towards the sand nozzle of the hydrocyclone.

 When the bumpers are made in the form of an upper and lower shortened epicycloid relative to the entrance to the drain pipe and in a section perpendicular to the axis of the hydrocyclone, the movement of the separated flows is smoother with minimal turbulence without mutual deformation with relatively quiet periodic disturbances both inside and outside the drain pipe. This allows you to reduce the intensity of mixing of the separation products, it is quite efficient to release fine and light particles pressed by large and heavy grains from the stream moving along the cylindrical wall of the body to the sand nozzle of the hydrocyclone, and to increase the accuracy of separation. In addition, by reducing the influence of zones of local turbulization of flows, an increase in the productivity and life of the hydrocyclone is provided.

где A - радиус неподвижного круга, мм;
а - радиус подвижного круга, мм;
λ <1- постоянная;
Φ - центральный угол, градус
(см. кн. Бронштейн И.Н., Семендяев К.А. Справочник по математике. - М.: Наука, 1964, с. 110-111, рис. 56 б).Experimental studies have shown that to obtain the optimal forming surfaces of the drain pipe bumps, it is necessary to use the following equation for a shortened epicycloid in parametric form:

where A is the radius of the fixed circle, mm;
a is the radius of the rolling circle, mm;
λ <1 is a constant;
Φ - central angle, degree
)

 The radii of the fixed and moving circles, the constant λ <1, and the number of branches of a shortened epicycloid depend on the diameters of hydrocyclones and drain pipes, as well as the supply pressure in accordance with GOST 10718-81.

 The use of chippers as forming surfaces installed on the inner surface of the drain pipe, epicycloids (λ = 1) and elongated epicycloids (λ> 1) are irrational due to sharp edges and narrow teardrop-shaped fairings that are subject to rapid wear and do not meet the requirements for optimal shape chippers (see the book. Bronstein I.N., Semendyaev K.A. Handbook of Mathematics. - Moscow: Nauka, 1964, p. 109, fig. 54 a, p. 110, fig. 56 a).

 The execution of the bumpers relative to the entrance to the drain pipe with a total height not exceeding two diameters of the cylindrical part of the drain pipe corresponds to a section with an unsteady swirling flow movement. The location of the chippers at this height reduces the likelihood of a reverse axial movement of particles from the drain pipe towards the sand nozzle due to the creation in the radial direction of the zone of increased small-scale turbulence, pressure drops and speed. In turn, the cylindrical part of the discharge pipe, located above the bumpers located on the surface of the pipe, promotes efficient separation with minimal turbulence of particles by size and density, since this process begins immediately, near the place of suspension from the supply pipe into the cylindrical part of the hydrocyclone body while up to 50% of the particles are released.

 The implementation of the chippers in the form of a lower shortened epicycloid relative to the entrance to the drain pipe with a height not exceeding one third of the diameter of the cylindrical part of the drain pipe corresponds to the necessary height to prevent particles larger and heavier than boundary particles from falling into the drain pipe due to the creation in the radial direction of the zone of increased small-scale turbulence, drops pressure and speed.

 The location of the chippers above a given height does not have a positive effect on the operation of the hydrocyclone due to the narrowing of the annular channel in the cylindrical part of the hydrocyclone body, which intensifies the negative effect of the axillary flow and, consequently, the mixing of separation products.

 The implementation of the chippers in the form of an upper shortened epicycloid with a fixed circle equal to the diameter of the cylindrical part of the drain pipe allows not to violate the main regulatory parameter of the hydrocyclone: unloading ratio equal to the ratio of the diameters of the sand and drain holes.

 The implementation of the chippers in the form of a lower shortened epicycloid with a fixed circle equal to the diameter of the circumscribed circle of the upper shortened epicycloid determines the size of the branches and, ultimately, the area of the lower shortened epicycloid. The area of the lower shortened epicycloid increases the length of the particles in the hydrocyclone and contributes to their forced movement in the direction of the sand nozzle of the hydrocyclone. Particles of boundary fineness and separation density, which have loop-like motion paths, are mainly directed by the end part of the lower shortened epicycloid towards the lower hole and are discharged through the sand nozzle. This increases the separation efficiency due to the intensification of the outlet and subsequent discharge through the sand nozzle of large and heavy particles, as well as particles of boundary fineness and separation density.

 At the same time, chippers made in the form of a lower shortened epicycloid with an optimal end area exclude mutual deformation of flows: a drain pipe moving from above on the outer surface and chippers made in the form of a shortened epicycloid and coming from below from the conical part of the hydrocyclone.

 In FIG. 1 shows a general view of a hydrocyclone; in FIG. 2 is a section along AA in FIG. 1.

 The hydrocyclone consists of a cylinder-conical body 1 with a supply pipe 2, a drain pipe 3 with chippers installed on its inner surface, made in the form of a lower shortened epicycloid 4 and an upper shortened epicycloid 5 relative to the entrance to the drain pipe 3. The lower chipper 4 has an external 6 and an internal 7 surface, and the upper bump 5 has an external 8 and internal 9 surface of the sand nozzle 10.

 The hydrocyclone works as follows.

 The source material is fed through a supply pipe 2 into a cylinder-conical housing 1 of a hydrocyclone, thereby forming a rotating flow directed from top to bottom along a helical line. Under the action of centrifugal force, large and heavy particles are thrown to the wall of the hydrocyclone and then unloaded through the sand nozzle 10, and the stream of fine and light particles exits through the drain pipe 3. When it moves in the cylindrical part of the hydrocyclone, the flow receives periodic disturbance from the outer surfaces of 8 of the upper bumpers 5 and the outer surfaces 6 of the lower bumpers 4. Similarly, when it moves through the drain pipe 3 of the hydrocyclone, the flow receives periodic disturbance from the inner surface 9 of the upper baffles headers 5 and the inner surfaces 7 of the lower bumpers 4. This contributes to a more efficient material removal in the annular channel and drain pipe with minimal clogging due to the creation of zones of increased small-scale turbulence, pressure drops and speed.

 The present invention improves the separation efficiency due to the additional extraction of fine and light particles.

Claims (1)

 A hydrocyclone comprising a cylinder-conical housing, a supply pipe, a drain pipe with chippers on its surface, a sand nozzle, characterized in that the chippers are installed on the inner surface of the drain pipe and are made in the form of an upper and lower shortened epicycloid relative to the entrance to the drain pipe and in a section perpendicular the axis of the hydrocyclone, while the total height of the shortened epicycloid does not exceed two diameters of the cylindrical part of the drain pipe, and the height of the lower shortened epicycloid does not exceed one third of the diameter of the cylindrical part of the drain pipe, in turn, the fixed circle at the upper shortened epicycloid is equal to the diameter of the cylindrical part of the drain pipe, and at the lower shortened epicycloid, the diameter of the circumscribed circle of the upper shortened epicycloid.

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