SE457614B - TURBO CYCLONE - Google Patents

Description

457 614 10 15 20 25 30 35 _ 2 _ the container greatly affects the pressure properties of the centrifugal pump and_forcels automation of the separation of suspensions in these devices.

For the separation of very fine particles (with a size of less than 40 .mu.m), small diameter hydrocyclones (not more than 50 mm) are used, which have a low process capacity per so-called unit device and require that the suspension stream inside the hydrocyclone be rotated at high speed.

These disadvantages have been partially eliminated in turbo-cyclones (so-called centriclones), in which the suspension current in a separation chamber is turned by a paddle wheel arranged on a shaft of a drive device. The rotation of the suspension stream by means of the impeller directly in the separation chamber contributes to creating favorable conditions for stabilization and automation of the centrifugal classification of suspensions and makes it possible to increase the efficiency of the unit device (process capacity) and to create conditions for separation of fine particles. speed, as well as the need to hydraulically transport the suspensions through pipes.

A turbocyclone is previously known (compare, for example, Soviet Inventor's Certificate No. 633,610, published in 1978), which comprises a chamber for sucking in an exit suspension, which is connected to a pipe section for feeding the exit suspension, and a chamber for separating the starting suspension, which is provided with a tangential pipe piece for discharging a thickened product with coarse, heavy particles and with an axially cylindrical pipe piece for discharging a clarified product with fine, light particles. In the separation chamber, on the shaft of a drive device, a vane wheel is arranged, which lies next to the chamber for sucking in the output suspension. 10 15 20 25 30 35 4457 6'I4 ._ 3 ._ This known turbocyclone works in the following way. The suspension is fed from a sump through the inlet pipe piece and the chamber for sucking in the outlet suspension to the impeller rotating by means of the shaft of the drive device, which rotates the suspension about its center axis and throws the suspension in the form of a helical flow into the separation chamber. of the initial suspension. An outer helical suspension flow with coarse, heavy particles flows along the walls of the separation chamber and is discharged at the opposite end of the separation chamber through the tangential pipe section to discharge the thickened product with coarse heavy particles. The clarified (clear) product with fine, light particles from the internal helical flow is removed from the chamber to separate the outlet suspension through the axial cylindrical outlet pipe section. By removing the thickened product with coarse, heavy particles from the chamber to separate the starting suspension through the tangential pipe section, the concentration of the solid phase in the thickened product cannot be significantly increased.

Nor can the pollution of the thickened product be reduced with (otherwise) fine particles, the size of which is equal to the size of the particles removed with the clarified product, especially when the concentration of the solid phase in the starting suspension is low. The concentration of the solid phase in the thickened product can only be increased, the near-separation products are removed at the opposite hall, analogous to what is carried out in village cyclones.

The thickened and the cleared (clear) product are discharged to opposite halls in turbocyclons, the impellers of which are supported by a hollow rotor, the side wall of which is provided with a slide and which is connected to a shaft of a drive device, which simultaneously acts as an axial cycle. clear outlet pipe piece for removing the 4557 6'14 10 15 20 25} 0 35 _ 4 _ clarified product from the chamber for separating the exit suspension. A curbocycion for the reduction of suspensions is known in the past (compare, for example, the Soviet inventor fi ifikazeu No. 528 120 published in 1976), in which a thickened and a clarified product is removed in opposite directions. This known tergocyclone comprises on the one hand a chamber intended for suction of an outlet suspension, which is connected to an inlet pipe section for feeding the outlet suspension, and on the other hand a chamber intended for separating the outlet suspension, which is provided with an axial outlet for the outlet of the outlet. coarse, heavy particles and a container for collecting the clarified product with fine, light particles, which container is provided with an outlet pipe section for removing the clarified product, wherein the separation chamber and the collection container are arranged on both sides of the intake chamber. Inside the separation chamber and the collecting container is arranged a hollow rotor, the side wall of which is provided with a heel for discharging the clarified product and which is connected to the shaft of a drive device and provided with a paddle wheel, which is arranged between the suction chamber and the separation chamber for the separation chamber.

This known phenocyclone works in the following way.

A suspension from a sump is fed through the inlet pipe section and the chamber for sucking in the outlet suspension to the impeller rotating on the hollow rotor, which rotates the suspension about its center line and ejects the suspension in the form of a helical flow into the separating chamber. An outer (externally) helical suspension flow with coarse, heavy particles flows along the walls of the separation chamber and is discharged at its opposite end. 5. through the axial outlet pipe section for discharging the pre-augmented product. An internal (internal) helical suspension-shaped, light particles are reversed (switched to the opposite direction of flow) and inserted through the hollow rotor and the heels accommodated in its side wall into the collection container for the clarified product, from which it removed through the tangential pipe section.

However, by arranging the impeller on the hollow rotor, through which the clarified product is removed from the separation chamber, the flow area of the starting suspension flow is reduced, which greatly reduces the separation capacity of the turbocyclone.

The known turbocyclons are provided with impellers in the form of a radial-type centrifugal impeller, which is built up of a system of vanes which are curved, seen in a plan view, and fastened to the plates perpendicular to the axis of rotation of the impeller. The low throughput of the centrifugal-type impellers is due to the small diameter of the annular opening around the hollow rotor or the shaft connected to the drive device, through which the output suspension is fed into the separating chamber. e In the flotation enrichment of beneficial affossil and in the classification and dewatering of suspensions which have been treated with surfactants and contain a considerable amount of air bubbles in foam form, the area of the centrifugal impellers of the known turbocyclons is layered in such a way that the air bubbles collect in paddle wheels. its inlet cross section and breaks the continuous beam of the suspension flow, so that the suction of the suspension ceases, the process capacity of the turbocyclone is sharply reduced. and the suspension is fed batchwise into the separation chamber. The same occurs during the operation of the suspension in pressure-type hydrocyclones, when the suspension is fed into these hydrocyclones by means of a centrifugal pump.

The suspension is fed into the separation chamber by means of the paddle wheel constructed in the form of a radially directed, twisted beam, which leads to the walls of the separation chamber in the area of the paddle wheel being intensively worn by grinding.

In the known turbo cyclones, where the clarified product with fine, light particles is removed from the separation chamber for the exit suspension through the hollow rotor, the side wall of which is provided with a slippery surface, coarse particles are introduced from the chamber for suction of the initial suspension partly directly into the suspension. for collecting the clarified product with fine particles through a gap between the rotating rotor and a partition wall arranged between the suction chamber and the collection container. This leads to the clarified product being contaminated and the separation of the suspension becoming less efficient.

Known contact type and non-contact type sealing devices for sealing annular gaps (for example sealing gaskets, sealing rings, labyrinth and cuff type sealing devices, helical palinairers) are ineffective due to the fact that the suspension exhibits a high concentration of hair. release articles. Nor can these sealing devices completely prevent coarse particles from being introduced into the collection container for the clarified product as a result of the geometric dimensions of the sealing devices changing during the work process.

FIELD OF THE INVENTION The main object of the present invention is to provide such a turbo cyclone for separation suspensions, e.g. treated with surfactants and suspensions with a considerable amount of air bubbles, in which the impeller and other structural elements are designed in such a way that one can increase the concentration of the solid phase in the thickened product and reduce the pollution of this product with fine hard particles in the event of significant changes in the concentration of the solid phase in the starting suspension, while the turbo cyclone provides high process capacity while delivering very fine particles (with a size of less than 40 μm) to the clarified product.

This object is achieved according to the present invention by means of a turbocyclone for separating suspensions and comprising on the one hand a guide vane provided and for suction of an outlet suspension intended for connection, which is connected to an inlet pipe section for feeding the outlet suspension, and a compartment for separating is provided with a coaxial outlet pipe piece for discharging a thickened product with coarse, heavy particles, and on the other hand a container for collecting a clarified product with fine, light particles, which container is provided with an outlet pipe piece for discharging the clarified product, the separation chamber and the collection container being arranged on opposite sides of the intake chamber, while inside the intake chamber, the separation chamber and the collection container a hollow rotor is coaxially arranged, the side wall of which is provided with the heel for discharging the product which is connected to an ax 1 to a drive device and provided with an impeller, which is arranged between the suction chamber and the separation chamber for the outlet suspension, and a sealing device. The characteristic of the invention is that the impeller consists of a sleeve with vanes, which are arranged freely projecting from the hollow rotor and whose coaxial cylindrical sections consist of profiles which are inclined relative to the axis of rotation of the hollow rotor.

In order to reduce the turbulence in the outlet suspension, it is suitable that the turbocyclone is provided with a control device, which is arranged in the intake chamber of the outlet suspension and built up in a helical format, shaped around it. hollow rotor wound band, the ends of which lie next to the upper and lower walls of the inlet pipe section, respectively, for feeding the outlet suspension. In order to prevent coarse particles from the suction chamber for the starting suspension from possibly being introduced into the collecting container for the clarified product, it is suitable that the turbocyclone according to the invention is provided with a contactless sealing device which is arranged between the suction chamber for the starting suspension and the storage suspension. the clarified product and 'consists of a (nut) washer with a conical inside, which is arranged so that a gap is left between the washer and an annular projection with a conical outside, which is ~ Bt-shaped near a center hole in the partition wall between the chamber for suction of the output suspension and the collecting container for the clarified product, while the outside of the washer is provided with grooves inclined relative to the axis of rotation of the rotor, the direction of inclination of which coincides with the direction of inclination of the vanes of the impeller.

BRIEF DESCRIPTION OF THE DRAWINGS The invention is described in more detail below with reference to the accompanying drawing, in which Fig. 1 schematically shows the turbo cyclone according to the present invention for separating suspensions, a Snitz: along line IILII 1 rig. 1, section along the line III-III in Fig. Contactless sealing device, Fig. Wheel and Fig. Paddle. Fig. 2 shows vig. Fig. 3 shows a 1, Fig. 4 shows a 5 shows a paddle 6 shows the cross-sectional shape of the paddle wheel Preferred embodiment of the invention The tour proposed according to the present invention 35 - 457 614 _ 9 _. The housing cyclone for separating suspensions comprises a cylindrical chamber 1 (Figs. 1, 2) for sucking in an outlet suspension and an inlet pipe section 2 connected to the chamber 1 for feeding the outlet suspension.

The chamber 1 for sucking in the output suspension is located on one side next to a Cylinda mechanical chamber 3 for separating the output suspension. An outlet pipe piece 4 for discharging a thickened product with coarse, heavy particles is attached to a tip for the comic part of the separation chamber 3.

Adjacent to the opposite side of the suction chamber 1 is a container 5 (Figs. 1, 3) for collecting a clarified product with fine, light particles. The collection container 5 is provided with an outlet pipe section 6 for discharging the clarified product. The chamber 1 and the collecting container 5 are separated from each other by means of a partition wall 7, which is provided with a center hall for receiving a hollow rotor 8, which is axially arranged inside the chambers 1, 3 and the collecting container 5.

The hollow rotor 8 is intended to simultaneously function as an outlet pipe section for discharging the clarified (clear) product with fine, light particles from the chamber 3 to the collecting container 5. The clarified product is intended to be discharged from the rotor 8 to the collecting container 5 through a hole 9 received in the sia wall of the returns. The rotor 8 is connected to a shaft 10 of a drive device.

On the hollow rotor 8 an axial type paddle wheel 11 is arranged between the suction chamber 1 and the separating chamber 3. Inside (i) the suction chamber 1 for the outlet suspension, a regulating device, which consists of a helical shape, is wound in front of the impeller 11, around the hollow rotor 8 wound strip 12. One end of the strip 12 lies next to an upper wall of the inlet pipe section 2 for inlet pipe section 2. the outlet suspension, while the other end of the belt 12 adjoins the lower wall of the inlet pipe 2. 457 614 10 15 20 25 30 35 _10 _ In order to prevent coarse particles from the suction chamber 1 for the starting suspension from possibly being introduced into the collecting container 5 for the removed product through a gap between the hollow rotor 8 and the center hole accommodated in the partition wall 7, the hollow rotor 8 is provided with a contactless sealing device, which has the shape of a washer 13 with a comic inside, which is arranged so that a small gap is left between the washer 13 and a ring-shaped projection 14 formed near the center hole of the partition 7. (Fig. 4) with conical outside. The outside of the washer 13 is provided with grooves 15 inclined relative to the axis of rotation of the rotor 8.

The impeller 11 (Fig. 1) is of the axial type and is made up of several inclined, profiled blades 16 arranged on a hub (a sleeve) 17, which, each, are rotated a certain angle (Fig. 6) about and geem ekeviernes 16 min; walking radius on one eadem; that the angle of inclination of each vane 16 in relation to an axis of rotation perpendicular to the axis of rotation of the rotor 8 (Fig. 1) in the peripheral part of the vane 16 is less than the respective angle of inclination in the hub part of the vane 16.

The turbo cyclone of the present invention for separating suspensions operates in the following manner.

The starting suspension from a buffer leg allyr (not shown in the drawing figures) is fed to the thickness 2 (fig. The helical band (screw band) 12 and fed to the impeller wheel 11. By the fluid flow dynamically interacting with the system of the inclined vanes 16 (Fig. 5), the suspension is sucked in the space between the vanes 16, at the same time as it is rotated about the axis of rotation of the hollow shaft 8 and under pressure is fed in the form of a screw-like flow 1 evaporation chamber 3 '(Fig. 1), which flow produces a centrifugal force field in which the fixed particles At the same time through the inlet pipe 1) in the suction chamber, flows along the suspension flow radially in the direction of the hollow rotor 8. center shaft, dragging coarse, heavy particles after fine, light ones under the influence of the resistive forces and inertia, whereby they flow in the external helical flow out behind the walls of the separation chamber 3 and at the same time is removed in the form of a thickened product from the separation chamber 3 through the axial outlet pipe section 4. Together with the coarse particles a small part of the liquid phase is removed. the concentration of solid particles and the size of these particles are adjustable depending on the inner diameter of the outlet hole of the pipe piece 4. The fine, lighter particles together with a considerable amount of the liquid phase of the suspension flow radially towards the center axis of the hollow rotor 8, form an internally helical flow, which changes its flow direction to the opposite and is removed from the separation chamber 3 through the rotating hollow rotor 8 and the heel 9 accommodated in its side wall to the collection container 5 for the clarified product, and discharged from the turbo cyclone through the outlet pipe piece 6. Thus, the clarified product is formed. As the output suspension in the suction chamber 1 flows directly along the helical belt 12, the turbulence of the suspension in front of the impeller 11 is damped (weakened), so that the flow transfer or separation capacity of the turbo cyclone increases and the energy consumption for turning the impeller. The high separation capacity (efficiency) of the turbocyclone is ensured mainly by the suitable constructive design of the impeller 11, namely because it is of the axial type, which in other words means that the flow-through part of the intake and separation chambers 1 and 3, respectively, have elongated shape. the vanes 16, through which the entire output suspension is pumped, have large dimensions. Since the suspension is pumped 457 614 10 15 20 25 30 35 _12 .. by the impeller 11 in the axial direction, the walls of the suction and separation chambers 1 and 3, respectively, are worn by grinding to a lesser extent, and the suspension is not layered into a liquid phase and an air phase (gas phase ), when separating with the turbocyclone according to the invention separated with surface-treated acene pre-auxes. The contactless sealing device in the form of the washer 13 prevents coarse particles from the suction chamber 1 from being introduced into the collection container 5 for the clarified product. It works as follows.

The suspension, which is inserted into the gap between the conical outside of the annular ridge 14 (Fig. 4) and the conical inside of the washer 13, is pumped away from the gap through the inclined separator 15 back to the inlet chamber 1, so that a circulating flow is formed. as the washer 13 with the inclined grooves 15 also constitutes an axial type impeller. This helps to prevent coarse particles from possibly being introduced into the container 5 for the clarified product through the gap between the rotating hollow rotor 8 and the center hole accommodated in the partition wall 7.

The constructive design of the impeller 11 (Fig. 1) proposed by the present invention, the regulating device and the contactless sealing device have thus made it possible to provide a new hydromechanical device for classifying suspensions, i.e. and s.k. turbocyclone, which is characterized by high efficiency and separation efficiency.

The turbocyclone proposed according to the present invention can also be used to advantage for separating suspensions treated with surfactants, for example flotation concentrates obtained at enrichment plants. The proposed constructive design of the turbo-cyclone makes it possible, depending on the diameter of the impeller 11 and the diameter of the suction and separation chambers 1 and 3, respectively, to provide the hydromechanical chambers 1 and 3, respectively. classification devices with a classification capacity of up to soo-soo m3 / n intended to operate at a concentration of 2-50% of solid particles in the starting suspension.

Such classification devices can therefore be used in many industries. For example, in the enrichment of useful fossils and in chemical process technology, the turbocyclones according to the present invention can be used for classifying suspensions in atomization, slurrying and thickening steps for polyfractional suspensions. In the building materials industry, the turbo cyclones can find use in obtaining sand with different particle sizes. The turbocyclons proposed according to the present invention can also be used for purifying drinking water from solid particles and for purifying industrial wastewater.

A single turbocyclone of the type proposed according to the invention can replace a batch of small diameter hydrocyclones driven by a centrifugal pump for the separation (isolation) of fine particles with a size of from 5 to 40 microns.

In a number of cases, by using the turbocyclones according to the invention, the need to hydraulically transport suspensions through pipelines can be completely eliminated and the specific electricity consumption for hydromechanical classification and clearance of suspensions can be reduced by 10-15%.

Industrial Applicability The turbocyclone proposed according to the present invention is preferably used for the separation of both highly concentrated (50% solid phase) and highly dilute (2% solid phase) suspensions, for isolating fine particles (slurry particles) and liquid phase true for separation of with surfactants treated suspensions and suspensions, which contain a significant 457 614 _14. _ .. amount of gas or air bubbles. The turbo cyclone of the present invention can be used to classify suspensions in an atomization step. '

Claims (3)

457 614 15 P a t e n t k r a v A turbo-cyclone for separating suspensions and comprising a guide vane provided for and intake of an exit suspension, which is connected to an inlet pipe section for feeding the exit suspension, and a chamber intended for separating the exit suspension with a chamber (3) a coaxial outlet pipe piece (4) for discharging a thickened product with coarse, heavy particles, and on the other hand a container (5) for collecting a clarified product with fine, light particles, which container is provided with an outlet pipe piece (6) for discharging the clarified product, the separation chamber (3) and the collecting container (5) being arranged on each side of the suction chamber (1), while inside the suction chamber, the separation chamber and the collecting container a hollow rotor (8) is coaxially arranged, side wall is provided with holes for discharging the clarified product and which is connected to a shaft of a drive device and provided with a paddle wheel (11), which is arranged between the suction chamber (1) and the separation chamber (3) for the exit suspension, and a sealing device (13-15), characterized in that the paddle wheel (11) consists of a sleeve with paddles ( 16), which are arranged freely projecting from the hollow rotor (8) and whose coaxial cylindrical sections are constituted by profiles which are inclined relative to the axis of rotation of the hollow rotor (8). Turbocyclone according to Claim 1, characterized in that the guide vanes in the intake chamber (1) for the outlet suspension consist essentially of a helical shape, with clearances running around the hollow rotor (8), the ends of which are connected to one another by means of a vertical partition (12a, Fig. 2), which coincides with the inside of the inlet pipe section (2) for feeding the outlet suspension and which adjoins the upper and lower wall thereof, respectively. Turbocyclone according to claim 1, characterized in that the sealing device is contactless and arranged on the hollow rotor (8) between the suction chamber (1) for the starting suspension and the collecting container (5) for the clarified product and consists of a washer (13 ) with conical 457 614 inside, which is arranged so that a gap is left between the washer (13) and an annular projection (14) with conical outside, which is formed in the vicinity of a center hole in a partition wall (7 ) between the suction chamber (1) for the starting suspension and the collecting container (5) for the clarified product, while the outside of the washer (13) is provided with grooves (15) inclined in front of the axis of rotation of the rotor (8), relating to which direction of inclination coincides with the direction of inclination of the vanes (16) of the impeller (11).