RU2310517C1 - Hydraulic cyclone-flotator - Google Patents

Abstract

FIELD: chemical industry; devices for separation of the non-uniform liquid systems under action of the centrifugal forces.

SUBSTANCE: the invention is intended for separation of the non-uniform liquid systems under action of the centrifugal forces. The hydraulic cyclone-flotator contains the cylindrical body with the porous permeable lateral wall and the annular collector for gas feeding in the body, the fitting pipe for feeding of the gas in the collector, the fitting pipe of feeding of the suspension into the hydraulic cyclone body, the fitting pipe for the foam withdrawal and the unloading device. In the annular collector there is the device for distribution of the gas pressure made in the form of the annular elements mounted coaxially to the body with the capability of the independent motion in the axial direction and having the disk shape in the cross section passing through the axis of the body of the hydraulic cyclone. The diameter of the cross-section of the annular elements is increasing, and the spacing interval between the adjacent annular elements is diminishing in the process of the decrease of the spacing interval starting from the fitting pipe of feeding of the suspension into the body. The fitting pipe of feeding of the gas into the collector is installed tangentially and supplied with the control valve. The technical result of the invention is the increase of the separating capability at the expense of distribution of the volumetric share of the bubbles of the gas fed through the porous permeable lateral wall of the body, the appropriate distribution of the gas pressure in the axial direction in the annular collector for feeding of the gas into the hydraulic cyclone body.

EFFECT: the invention ensures the increased separating capability of the hydraulic cyclone due to distribution of the volumetric share of the gas bubbles fed through the porous permeable lateral wall of the body, the corresponding distribution of the gas pressure in the axial direction in the annular collector for the gas feeding into the hydraulic cyclone body.

2 cl, 2 dwg

Description

The invention relates to the field of separation of heterogeneous liquid systems under the action of centrifugal forces, in particular to hydrocyclones for separation of suspensions by flotation, and can be used in chemical, petrochemical, microbiological, pulp and paper and other industries.

Known hydrocyclone-flotator (A.S. 973174 USSR, IPC V04C 9/00, publ. 11/15/82, BI No. 42) containing a cylindrical housing with a tangential inlet pipe, in which the cylindrical chamber is equipped with a tangentially installed tapered conical nozzle located coaxially with inlet pipe. Due to ejection, gases are released into the nozzles that are released during electrolysis of the liquid in the annular space between the body and the cylindrical chamber, which are used for flotation.

In this design of a hydrocyclone-flotator, secondary gas bubbles absorbed by ejection have a low dispersion, which reduces the efficiency of the flotation process and the separation capacity of the hydrocyclone.

Known hydrocyclone for separating gas from liquid (A.S. 1526836 USSR, IPC B04C 5/02, publ. 07.12.89, BI No. 45), containing a tangential inlet pipe with a confuser equipped with a static swirl, made in the form of a pipe with periodic extensions and narrowing the section. In the constriction of the inlet pipe due to a sharp decrease in pressure, an increase in the size of microbubbles and their partial coagulation occurs.

The implementation of the inlet nozzle of the hydrocyclone in the form of a pipe with periodic extensions and narrowing of the section leads to a sharp increase in the hydraulic resistance of the apparatus and increase energy consumption for the process. In addition, an increase in the size of microbubbles adversely affects the kinetics of the flotation process of small particles.

Known hydrocyclone-flotator (A.S. 1607960 USSR, IPC V04C 9/00, publ. 11/23/90, BI No. 43), including an aerator and electrodes connected to a direct current source, in which to increase the efficiency of the work the electrodes are made in the form of vertical plates mounted coaxially with the housing, placed with a gap and with an angle of inclination in the direction opposite to the feed direction of the initial mixture. The placement of the plates allows you to adjust the total area of the electrodes, which makes it possible to optimize the conditions of aeration and flotation.

In this design of the hydrocyclone-flotator, the installation of plates makes it difficult to transport flotation complexes to the surface of the suspension and reduces the separation ability of the hydrocyclone. In addition, for the process of electrolysis of water requires additional energy.

Known gas-liquid separator (Patent 2071838 of the Russian Federation, IPC B04C 3/06, B01D 43/00, publ. 01.20.97, BI No. 2), containing a cylindrical housing of a hydrocyclone, an ejector with nozzles for supplying the processed liquid and gas, connected to located coaxially above the hydrocyclone a mixing chamber, the outlet end of which is located inside the hydrocyclone and is equipped with a guiding apparatus and a conical bell under it adjacent to the hydrocyclone body and perforated by tangential holes.

When separating suspensions by flotation in a separator of this design, the use of gas ejection with liquid and the installation of a bell adjacent to the body of the hydrocyclone perforated with tangential holes lead to a significant increase in the total hydraulic resistance of the apparatus and an increase in energy consumption for the separation process.

Known hydrocyclone with gas supply (US Patent 0473566, IPC B03D 1/14, B04C 5/10; B04C 5/103; B04C 5/14, published 04.03.92, Bull. 92/10), containing the first vortex chamber with porous a wall in the form of a surface of revolution through which gas and liquid saturated with gas are supplied from the collector, which is axially divided into two sections, to form small bubbles. The second vortex chamber is formed by a conical section of the casing and a casing in the form of an inverted cone with an axial hole for gas passage mounted on brackets connecting it to the casing, which intensifies the separation in the second vortex chamber.

In this design of the hydrocyclone, a separate supply of zones of gas and liquid saturated with gas is provided over the zones in the first vortex chamber, which causes the presence of only large-sized bubbles in one zone, and only small fractions in the second zone, therefore, the high cyclone of this design does not provide the value of the kinetic constants of flotation and when separating suspensions containing a polydisperse solid phase, a high separation ability cannot be achieved.

Known hydrocyclone with an adjustable diaphragm (US Patent 5560818, IPC B03D 1/24; B04C 5/16; B04C 5/181, publ. 1.10.96), which has a cylindrical body into which gas is supplied from the collector along the entire height for foam formation, having at least one gas inlet through a porous diaphragm made in the form of a surface of revolution. At the bottom of the hydrocyclone there is a cone-shaped plug that overlaps the side opening for the exit of the treated suspension. The flow rate in the hydrocyclone is controlled by changing the size of the side hole when moving the plug and thus many hydrocyclone operating parameters are supported.

The simultaneous impact on many operating parameters of the hydrocyclone by changing the size of the hole for the outlet of the treated suspension does not provide the optimal operating mode of the hydrocyclone and high separation ability.

The closest to the proposed design of the hydrocyclone-flotator in terms of technical nature and the technical result achieved is the method of monitoring the separation efficiency in a hydrocyclone (US Patent 4876016, IPC С02F 1/38; В01D 17/038; В04С 5/18; В04С 11/00, publ. 10.24.89), which consists in regulating the amount of air supplied to the hydrocyclone through a perforated wall of the body with a lining of porous material from the reservoir, depending on the concentration of oil in purified water. The separation of oil products from water occurs by flotation during the passage of air bubbles through water saturated with oil products.

In accordance with this method, regulation is carried out without taking into account the distribution of the concentration of oil products in water over the height of the hydrocyclone and provides for uniform air supply to the hydrocyclone through a perforated wall of the body with a lining of porous material, which does not provide high values of the degree of extraction of oil products in areas with a significant concentration of them in water . As a result, the separation ability of the hydrocyclone of this design is low.

The objective of the invention is the creation of the design of a hydrocyclone-flotator for the separation of suspensions, providing high separation capacity.

The technical result that can be obtained by carrying out the invention is to increase the separation ability of the hydrocyclone-flotator due to the distribution of the volume fraction of gas bubbles supplied through the porous permeable side wall of the body to the hydrocyclone in the axial direction is proportional to the volume fraction of solid particles bound to the complexes, in suspension by appropriate axial distribution of gas pressure in the annular manifold for supplying gas to the hydrocyclone body.

The specified technical result is achieved in that in a hydrocyclone-flotator comprising a cylindrical body with a porous permeable side wall and an annular manifold for supplying gas to the hydrocyclone body, a gas supply pipe to the manifold, a suspension supply pipe to the hydrocyclone body, a foam discharge pipe and an unloading device moreover, in the annular manifold is installed a device for distributing gas pressure, made in the form of annular elements mounted coaxially to the body of the hydrocyclone with the possibility of dependent displacement in the axial direction, having a circle shape in the section passing through the axis of the hydrocyclone body, and the diameter of the cross section of the ring elements increases, and the distance between adjacent ring elements decreases as the distance from the suspension supply pipe to the hydrocyclone body decreases, and the gas supply pipe to the manifold installed tangentially and equipped with a control flap. The ring elements are mounted on telescopic rods, which are a set of hollow cylinders rigidly connected to the corresponding ring elements.

The implementation of the device for the distribution of gas pressure in the form of annular elements in the form of a circle in section, passing through the axis of the hydrocyclone body, allows to reduce the gas pressure drop across the hydraulic resistance formed by the annular element, and to reduce turbulence when the gas element flows around the annular element in the manifold, and thus to increase the uniformity of the distribution of gas pressure in the reservoir and the volume fraction of gas bubbles entering through the porous permeable side wall of the body into the hydrocyclone, axial direction, which leads to an increase in its separation ability.

An increase in the diameter of the cross section of the annular elements passing through the axis of the hydrocyclone body and a decrease in the distance between adjacent annular elements as the distance from the suspension supply pipe to the hydrocyclone decreases, the axial pressure gradient of the gas in the manifold increases as the distance from the suspension supply pipe to the body decreases hydrocyclone and create a distribution of gas pressure in the reservoir and the volume fraction of gas bubbles entering through a porous permeable side wall ku hydrocyclone body in the axial direction proportional to the volume fraction of solid-phase particles are bound in complexes, in suspension, which leads to increased separation capacity of the hydrocyclone.

The installation of ring elements in the collector with the possibility of independent movement in the axial direction and the installation of a control flap in the gas supply pipe to the collector provide the possibility of flexible control of the gas pressure distributions in the collector and the volume fraction of gas bubbles entering the hydrocyclone through the porous wall of the body in the axial direction, in compliance with the operational parameters of the hydrocyclone and increase its separation ability.

The tangential installation of a gas supply pipe into the collector improves the uniform distribution of the gas flow from the collector through the porous permeable side wall of the body into the hydrocyclone in the circumferential direction and increases the separation ability of the hydrocyclone.

Figure 1 shows the hydrocyclone-flotator of the proposed design, General view; figure 2 is a section along aa.

The hydrocyclone-flotator contains a cylindrical body 1 having a porous permeable side wall, with a cover 2 and a pipe for feeding slurry 3, mounted tangentially in the upper part of the body, an unloading device made in the form of two concentrically mounted annular vertical partitions 4 and walls 5 forming channels 6 for the passage of clarified separation products, at the outlet of which control devices 7 are installed, which can be rotated relative to the axes 8, and a nozzle 9 for removing foam saturated astitsami discharge product. Gas is supplied to the hydrocyclone from the annular collector 10 through the porous wall of the housing 1. Gas enters the manifold 10 through a nozzle 11 installed tangentially in its lower part and provided with a control valve 12. A device for distributing gas pressure in the form of annular rings is installed in the manifold 10 elements 13 mounted coaxially to the body of the hydrocyclone with the possibility of independent movement in the axial direction, having the shape of a circle in cross section passing through the axis of the body of the hydrocyclone. The diameter d of the cross section of the annular elements increases, and the distance between adjacent annular elements s decreases as the distance from the nozzle 3 for supplying the suspension to the body of the hydrocyclone decreases. The ring elements 13 are mounted on telescopic rods 14, which are a set of hollow cylinders rigidly connected to the corresponding ring elements.

The hydrocyclone flotator is designed to carry out a two-stage pressure flotation process and works as follows. An initial stream containing a suspension pre-saturated with gas at an increased (up to 0.8 MPa) pressure is supplied to the hydrocyclone body 1 having a porous permeable side wall from a nozzle 3 mounted tangentially in the upper part of the hydrocyclone body. When the pressure decreases in the hydrocyclone body to atmospheric, a supersaturation of the dissolved gas is created and the suspension “boils”. The suspension entering the housing 1 of the hydrocyclone flows off, forming a rotating film, down its walls. Particles of the solid phase under the action of the centrifugal inertia force move toward the wall of the hydrocyclone body, and gas bubbles under the action of the buoyant centripetal force of Archimedes move toward them to the surface of the film. At the first stage of pressure flotation, when particles of a solid phase collide with gas bubbles released from a suspension, the formation of flotation complexes that carry solid particles to the surface of the film in the foam layer occurs.

Through the porous side wall of the housing 1, secondary gas bubbles from the reservoir 10 are fed into the hydrocyclone. Secondary gas bubbles, which are an order of magnitude larger in diameter than the bubbles of gas released from the suspension when pressure is reduced, have a significantly higher rate of ascent to the film surface than the complexes formed. At the second flotation stage, the secondary gas bubbles, colliding with the pop-up complexes, form secondary complexes with them, in which the particle makes a bridge between the bubbles, which quickly rush to the film surface and are removed into the foam layer. Foam is removed from the hydrocyclone through the pipe 9, and clarified products through the channels 6 of the discharge device.

Due to the fact that the diameter of the secondary gas bubbles supplied through the porous permeable side wall of the hydrocyclone body 1 is an order of magnitude greater than the diameter of the gas bubbles released from the suspension in the first stage of pressure flotation and is much larger than the diameter of the particles of the solid phase, the efficiency of collision of free particles the solid phase with secondary gas bubbles according to known methods of its calculation is small and can be neglected. In addition, the concentration of free particles of the solid phase decreases rather quickly and becomes negligible after the suspension is fed into the hydrocyclone body due to the formation of flotation complexes with gas bubbles released from the suspension in the first flotation stage.

The volume fraction of solid phase particles that form flotation complexes with bubbles of gas released from the suspension changes in the direction of the axis of the hydrocyclone according to well-known laws depending on the design and operating parameters of the hydrocyclone, according to which the gradient of the volume fraction of solid particles bound into complexes increases in the axial direction as the distance from the nozzle 3 for supplying the suspension to the hydrocyclone body decreases. Consequently, the separation ability of a hydrocyclone can be increased by distributing the volume fraction of bubbles of the secondary gas entering through the porous wall of the housing 1 in proportion to the volume fraction of particles of the solid phase bound into complexes in suspension, as a result of which, according to the kinetic equation of the flotation process, the volume fraction of particles of the solid phase will increase extracted from the suspension by bubbles of secondary gas. Considering that in the axial zone of the upper part of the hydrocyclone body 1, a vacuum is maintained, and the centrifugal pressure in the suspension film on the wall decreases as the distance from the suspension supply pipe 3 to the hydrocyclone body increases due to axial velocity attenuation in the axial direction, pressure changes in the film of the suspension on the wall can be neglected, assuming that the distribution of the volume fraction of gas bubbles entering the hydrocyclone through the porous wall of the housing 1 is proportional to the pressure distribution I have gas in the reservoir 10 in the axial direction. Therefore, the necessary distribution of the volume fraction of the secondary gas bubbles can be achieved by changing the distribution of the gas pressure in the manifold 10 in the axial direction. For this purpose, a gas pressure distribution device is installed in the manifold 10, made in the form of annular elements 13 mounted coaxially to the hydrocyclone body 1 with the possibility of independent axial movement, having the shape of a circle in cross section passing through the axis of the hydrocyclone body. The diameter of the cross section of the annular elements d increases, and the distance between adjacent annular elements s decreases as the distance from the nozzle 3 for supplying the suspension to the body of the hydrocyclone decreases. The ring elements 13 are mounted on telescopic rods 14, which are a set of hollow cylinders 4 rigidly connected to the corresponding ring elements 13.

The implementation of the device for the distribution of gas pressure in the form of annular elements 13 having a circle shape in cross section passing through the axis of the hydrocyclone body allows to reduce the gas pressure drop across the hydraulic resistance formed by the annular element and to reduce turbulence when the gas element flows around the annular element in the manifold, such thus increasing the uniformity of the distribution of gas pressure in the reservoir 10 and the volume fraction of gas bubbles entering through the porous wall of the body into the hydrocyclone in the axial direction, which leads to an increase in its separation ability.

An increase in the diameter d of the cross section of the ring elements 13 passing through the axis of the hydrocyclone body 1, as the distance from the suspension supply pipe 3 to the hydrocyclone decreases, leads to an increase in pressure drops across the hydraulic resistances formed by the ring elements, as the distance from the suspension supply pipe 3 decreases to hydrocyclone body. Regularities in the change in the diameter d of the cross section of the annular elements 13 and the distance s between adjacent annular elements increase the pressure gradient in the manifold 10 in the axial direction as the distance from the suspension supply pipe 3 to the hydrocyclone decreases and allows obtaining gas pressure distributions in the manifold 10 and the volume fraction of bubbles gas flowing through the porous wall of the housing 1 into the hydrocyclone in the axial direction, proportional to the distribution of the volume fraction of solid particles bound in complexes, in the suspension, resulting in increased separation capacity of the hydrocyclone.

The ring elements 13 are installed in the manifold 10 with the possibility of independent movement in the axial direction, which, together with the installation of the control flap 12 in the pipe 11 for supplying gas to the collector, makes it possible to flexibly control the gas pressure distribution in the manifold 10 in the axial direction in accordance with the operating parameters of the hydrocyclone.

The pipe 11 for supplying gas to the manifold 10 is installed tangentially, which improves the uniform distribution of the gas flow from the collector 10 through the porous wall of the housing 1 into the hydrocyclone in the circumferential direction and increases the separation ability of the hydrocyclone.

Thus, the proposed design of the hydrocyclone-flotator allows you to create the distribution of gas pressure in the reservoir and the volume fraction of gas bubbles entering the hydrocyclone through the porous wall of the body in the axial direction, proportional to the distribution of the volume fraction of solid particles bound into complexes in suspension and makes it possible flexible regulation of the gas pressure distribution in the reservoir in accordance with the operating parameters of the hydrocyclone, which leads to an increase in its separation ability.

Claims (2)

1. A hydrocyclone-flotator comprising a cylindrical body with a porous permeable side wall and an annular manifold for supplying gas to the hydrocyclone body, a gas supply pipe to the manifold, a suspension supply pipe to the hydrocyclone body, a foam pipe and an unloading device, characterized in that An annular manifold is equipped with a gas pressure distribution device made in the form of annular elements mounted coaxially with the hydrocyclone body with the possibility of independent movement in the axial direction in the form of a circle in the cross section passing through the axis of the hydrocyclone body, and the diameter of the cross section of the ring elements increases, and the distance between adjacent ring elements decreases as the distance from the suspension supply pipe to the hydrocyclone decreases, and the gas supply pipe to the manifold is installed tangentially and equipped with control flap. 2. The hydrocyclone-flotator according to claim 1, characterized in that the annular elements are mounted on telescopic rods, which are a set of hollow cylinders rigidly connected to the corresponding annular elements.

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