RU2212281C1 - Hydraulic cyclone - Google Patents

Abstract

FIELD: separation of heterogeneous liquid systems under action of centrifugal forces; separation of suspensions; chemical, petrochemical, microbiological, wood-pulp and paper industries. SUBSTANCE: proposed hydraulic cyclone includes cylindrical housing with supply branch pipe and cover, unloading unit and foam discharge branch pipe; supply branch pipe is made in form of injector having housing in form of Laval nozzle; it is mounted concentrically for longitudinal motion of air supply tube terminating on narrowing section of injector housing; its wall is perforated outer generatrix of horizontal section of injector housing is engageable with cylindrical surface of hydraulic cyclone housing. Separating capacity of hydraulic cyclone is increased due to attenuation of circumferential component of velocity of flow in way of axis of hydraulic cyclone. EFFECT: increased separating capacity of cyclone. 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 the separation of suspensions, and can be used in chemical, petrochemical, microbiological, pulp and paper and other industries.

 A device for separating suspensions (A.S. 1316123 USSR, IPC B 01 D 45/12, publ. 15.11.90, BI 42), containing a node for forming a suspension flow, made in the form of a distribution cone having rotation and having on the outside the surface is a single-start spiral strip and a multi-blade swirler installed at the level of the gas flow supply pipe.

 A disadvantage of the described device for separating suspensions is the high hydraulic resistance associated with the presence of a distribution cone and a multi-blade swirl in the apparatus, which leads to additional energy losses.

 A device for separating a suspension (A.S. 1137627 USSR, IPC B 01 D 45/12, 04 C 9/00, publ. 15.11.90, BI 42), in which, in order to increase the efficiency of separation and reduce the moisture content of the thickened suspension the suspension inlet pipe is installed inside the air inlet pipe with the possibility of longitudinal movement. The operation of this device is associated with large losses of energy of the gas stream for transportation of the suspension.

 A device for separating suspensions (A.S. 1389065 USSR, IPC B 01 D 45/12, publ. 15.11.90, BI 42), comprising an impeller with blades mounted for rotation, is provided with a device for ejecting the suspension, located above the collector input suspension and the collector of the solid phase.

 Ejection of a suspension through tangential slots by air flow is not accompanied by a restructuring of the velocity field in the swirling suspension film, and therefore, does not lead to a decrease in the attenuation rate of the peripheral component of the flow velocity in the direction of the apparatus axis and does not significantly increase the separation ability.

 Known hydrocyclone (A. p. 1150041 USSR, IPC B 04 C 5/08, publ. 15.04.85, BI 14) containing a cylindrical body with a tangential feed pipe and a cover, an unloading device made in the form of concentrically mounted partitions forming channels for the passage of classification products, at the outlet of which control devices are installed, in which the supply pipe is made equal in width to the radius of the housing and is equipped with vertical guide walls that repeat the shape of the pipe and housing and ending in the first erti circumference of the housing. In this case, the supply pipe is equipped with a spiral cover that smoothly passes into the housing cover.

 Due to the fact that the input and output of the flow is made over the entire width of the working space of the apparatus, the flow of the liquid phase in the radial direction is completely absent. This phenomenon makes it possible to eliminate undesirable zones of turbulent mixing of the suspension in the apparatus, as well as to reduce the hydraulic resistance of the hydrocyclone, however, in this hydrocyclone, the design features of the inlet pipe lead to a decrease in the rate of introduction of the separated suspension into the hydrocyclone and to a decrease in the separation factor, which, together with an increase in the thickness of the film to be separated suspension caused by an increase in the ratio of the cross-sectional area of the inlet pipe to the horizontal sectional area of the hydrocyclone body, leads to low values of separation ability.

 The closest to the proposed technical essence and the achieved result is a hydrocyclone with an adjustable diaphragm (US Patent 5560818, IPC B 03 D 1/24, publ. 01.10.96), which has a cylindrical shape and is designed to remove large particles from paper pulp that are separated with foam through the top hole. For the formation of foam in the apparatus, gas is supplied over the entire height, the formation of bubbles is ensured by the porous diaphragm. At the bottom of the hydrocyclone there is a cone-shaped plug that overlaps the side opening for the exit of the treated suspension. A manual mechanism is provided for moving the plug along the walls of the apparatus in a certain limit, thereby regulating the amount of outgoing pulp.

 The process of separation in such a hydrocyclone requires additional energy for pumping air through a porous diaphragm, in addition, the circumferential component of the flow rate quickly attenuates in the direction of the axis of the apparatus, which significantly reduces its separation ability.

 The objective of the invention is to provide a hydrocyclone design for the separation of suspensions by flotation, providing high separation capacity.

 The technical result that can be obtained by carrying out the invention is to increase the separation ability of a hydrocyclone by reducing the attenuation rate of the peripheral component of the flow velocity in the direction of the axis of the hydrocyclone, which is associated with a change in the radial distribution of the peripheral component of the velocity at the flow inlet to the hydrocyclone.

 The specified technical result is achieved in that the hydrocyclone for separating suspensions, containing a cylindrical body with a supply pipe and a lid, an unloading device and a pipe for removing foam, is equipped with a supply pipe made in the form of an injector consisting of a housing having the shape of a Laval nozzle and installed concentrically with the possibility of longitudinal movement of the tube for air supply ending in a section of the injector body tapering in the direction of flow and having a perforated end wall at the outlet ode, and the outer generatrix of a horizontal section of the injector body passing through the axis is made conjugated to the cylindrical surface of the hydrocyclone body.

 It is proposed to perform in a hydrocyclone a supply pipe in the form of an injector consisting of a housing having the shape of a Laval nozzle and mounted concentrically with the possibility of longitudinal movement of the tube for air supply.

 The execution of the injector body in the form of a Laval nozzle allows you to change the distribution of the peripheral component of the flow velocity at the inlet of the hydrocyclone, reduce the pressure loss to local resistances during the passage of the injector suspension flow, ensure good mixing of the suspension with air bubbles and suppress the turbulent velocity pulsations that are undesirable for the separation process.

 On the injector body section of the injector expanding in the direction of flow, the velocity in the flow regions adjacent to the walls decreases significantly, and in the center of the flow increases, resulting in a change in the radial distribution of the peripheral component of the flow velocity at the inlet of the hydrocyclone and due to a decrease in the friction forces in the flow regions, adjacent to the wall of the body of the hydrocyclone, reducing the attenuation rate of the peripheral component of the flow velocity in the direction of the axis of the hydrocyclone and increasing the separation capacity, causing the increase in centrifugal inertia.

 Possibility of longitudinal movement of the air supply tube provides regulation of the pressure created by the injector, which changes the volume of the suspension injected per unit time and the radial distribution of the peripheral component of the flow velocity of the suspension at the inlet of the hydrocyclone, which affects the performance of the hydrocyclone and separation capacity.

 The implementation of the end wall of the perforated air supply tube increases the efficiency of injection of the suspension with air by increasing the contact surface of the jets of the supplied air with the suspension, as well as increasing the uniformity of the distribution of air bubbles in the suspension and reducing their size, which leads to an increase in the separation ability.

 The implementation of the outer generatrix of a horizontal section of the injector body passing through an axis conjugated with the cylindrical surface of the hydrocyclone body provides a reduction in turbulent pulsations of the suspension flow rate at the inlet of the hydrocyclone, which leads to an increase in separation ability, as well as a decrease in hydraulic resistance at the flow inlet to the hydrocyclone and a decrease energy costs for the suspension.

 In FIG. 1 shows a hydrocyclone of the proposed design, general view; figure 2 is a section along aa.

 The hydrocyclone contains a cylindrical body 1 with a cover 2, an unloading device made in the form of two concentrically mounted annular vertical partitions 3, forming a channel for the passage of clarified separation products, at the outlet of which a control device 4 is installed, a nozzle for removing foam 5 saturated with particles of the separated product . The hydrocyclone is equipped with a supply pipe made in the form of an injector consisting of a housing 6 having the shape of a Laval nozzle and a concentric tube 7 for supplying air with a longitudinal movement mechanism 8 ending in a section of the injector body 6 tapering in the direction of flow and having a perforated end wall 9. The outer generatrix of the horizontal section of the injector body 6 passing through the axis is made conjugated to the cylindrical surface of the hydrocyclone body 1.

 The hydrocyclone works as follows. The suspension to be separated is fed into the injector, which consists of a housing 6 having the shape of a Laval nozzle and an air supply tube 7. On the section of the injector body 6 tapering in the direction of flow, the suspension is injected with jets of air supplied through the perforated end wall 9 of the tube 7.

 The execution of the injector body 6 in the form of a Laval nozzle allows you to change the distribution of the peripheral component of the flow velocity at the inlet of the hydrocyclone, reduce the pressure loss to local resistance during the flow of the injector suspension and ensure good mixing of the suspension with air bubbles and damping of turbulent velocity pulsations that are undesirable for the separation process.

 In a portion of the injector body 6 expanding in the direction of flow, the velocity in the flow regions adjacent to the walls decreases substantially, and increases in the center of the flow. As a result of the restructuring of the velocity profile in the section of the injector body 6 expanding in the direction of flow, the radial distribution of the peripheral component of the flow velocity at the inlet to the hydrocyclone changes. The speed of the suspension in the flow zone adjacent to the wall of the body of the hydrocyclone at the inlet of the flow into the hydrocyclone decreases, and increases in the region of the axis of the body of the injector 6, which, due to a decrease in the friction forces in the areas of flow adjacent to the wall, leads to a decrease in the attenuation rate of the peripheral velocity component flow in the direction of the axis of the hydrocyclone and an increase in separation capacity caused by an increase in centrifugal inertia.

 In the section of the injector body 6 expanding in the direction of flow, the formed air bubbles are mixed with the suspension, and the formation of flotation complexes begins when air bubbles collide with solid particles. The preliminary formation of part of the flotation complexes in the section of the injector body 6 expanding in the direction of the flow increases the separation ability of the hydrocyclone.

 When the suspension flow passes through the portion of the injector body 6 expanding in the direction of flow, the turbulent velocity pulsations that are undesirable for the separation process that occur when the suspension is injected with air are suppressed.

 The implementation of the perforated end wall 9 increases the efficiency of injection of the suspension with air, since the contact surface of the jets of air flowing from the perforation holes with the suspension increases with an increase in the number of perforation holes. The air supply through the perforated wall 9 also helps to increase the uniformity of the distribution of air bubbles in the suspension and to reduce their size, which leads to an increase in the separation ability of the hydrocyclone. The pressure created by the injector is controlled by the longitudinal movement mechanism 8 of the tube 7, due to which the amount of the injected suspension and the distribution of the peripheral component of the suspension flow velocity in the radial direction at the inlet of the hydrocyclone change, which affects the performance of the hydrocyclone and its separation ability.

 The suspension that enters the hydrocyclone, saturated with air bubbles, flows down, rotating, down the wall of the cylindrical body 1. In this case, the flotation process proceeds, which consists in the formation of flotation complexes in collisions of air bubbles with solid particles and their subsequent transportation to the free surface of the suspension film under the action of centrifugal inertia. On the free surface of the suspension film a foam is formed, saturated with particles of the solid phase, which is removed through the pipe 5 located in the cover 2 of the housing 1 of the hydrocyclone. The clarified suspension is discharged from the hydrocyclone through a discharge device made in the form of two concentrically mounted annular vertical partitions 3, forming a channel for the passage of separation products, at the outlet of which a control device 4 is installed.

 Due to the fact that the limiting stage of the flotation process in a hydrocyclone is the transportation of flotation complexes to the free surface of the film, a decrease in the attenuation rate of the peripheral component of the suspension flow velocity in the direction of the hydrocyclone axis, accompanied by an increase in the centrifugal inertia force acting on the flotation complexes, leads to an increase in separation ability.

 The outer generatrix of the horizontal section of the injector body 6 passing through the axis is made conjugated to the cylindrical surface of the hydrocyclone body 1. This ensures a decrease in turbulent pulsations of the flow rate of the suspension at the inlet of the hydrocyclone, which leads to an increase in separation ability, as well as a decrease in hydraulic resistance at the inlet of the flow to the hydrocyclone and a reduction in the energy consumption for supplying the suspension.

 Thus, the proposed design of the hydrocyclone intended for carrying out the flotation process can significantly reduce the attenuation of the peripheral component of the flow velocity in the direction of the hydrocyclone axis, as a result of which the speed of transportation of the flotation complexes to the surface of the suspension film is increased and the separation capacity is increased.

Claims (1)

 A hydrocyclone comprising a cylindrical body with a supply pipe and a cover, an unloading device and a pipe for removing foam, characterized in that the supply pipe is made in the form of an injector consisting of a body having the shape of a Laval nozzle and installed concentrically with the possibility of longitudinal movement of the air supply pipe, ending in a section of the injector body tapering in the direction of flow with a perforated end wall at the outlet, the outer horizontal section of the body also torus, passing through the axis is formed with a cylindrical mating surface of the hydrocyclone body.

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