RU2179893C2 - Centrifuge - Google Patents

Abstract

FIELD: devices for separation of liquid nonhomogeneous media under action of centrifugal forces; chemical, oil refining, food-processing, pharmaceutical and other industries. SUBSTANCE: centrifuge includes rotor mounted on shaft and assembled from two cone-shaped ferrules directed towards each other by their larger bases; lower ferrule is located for axial displacement for discharge of sediment and upper ferrule is provided with holes for introducing suspension. Disk located inside divides its interior into parts; receiving chamber located on lower ferrule is used for discharge of cleaned liquid. This chamber is formed by vertical partition secured on lower ferrule and provided with holes in its lower portion; fraction of flow section of these holes ranges from 1 to 3% of flow section of holes used for introducing suspension. Disk is provided with blades for rotation of suspension at angular velocity f rotation of rotor. EFFECT: enhanced efficiency of flow of cleaned liquid at rotor outlet; enhanced safety of process at separation of explosive suspensions. 1 dwg

Description

 The invention relates to a device for separating suspensions under the action of centrifugal forces, in particular to centrifuges, and can be used in chemical, oil refining, food, pharmaceutical and other industries.

 Known centrifugal apparatus for separating suspensions [1], including a housing mounted on the shaft of the impeller, consisting of profiled disks forming a chamber for entering the suspension and a downstream chamber for removing the clarified fraction, pipes for feeding the suspension and unloading sediment, a hollow shaft having a central a drain hole and a series of holes in the wall connecting the cavity of the shaft with the chamber for removal of the clarified fraction.

 The main disadvantage of this device is the low quality of the separation of the suspension due to the stirring up of the thickened suspension located in the apparatus body, the impeller of the rotor and capture of the finely dispersed solid phase by an upward flow of liquid entering the hollow shaft through the drain hole.

 A known centrifuge [2], containing a rotor, consisting of two conical plates facing one another with large bases, one of which is mounted with the possibility of axial movement.

 The disadvantages of this device are low productivity, limited by the area of the passage section of the gap between the plates, low quality separation of suspensions due to capture of the solid phase by the flow of purified liquid.

 The closest technical solution to the proposed one is a centrifuge [3], containing a rotor, consisting of two cone-shaped plates facing one another with large bases, one of which is installed with the possibility of axial movement, a filter for cleaning the liquid.

 The disadvantages of this device are low performance, limited by the filter area; insufficient degree of separation of the suspension due to the low speed of rotation of the rotor; the impossibility of using this centrifuge to separate suspensions containing potentially hazardous substances, due to incomplete removal of the solid phase from the rotor during the stop of its rotation, since solid particles settle on the inner surface of the rotor (filter).

 The technical result of the invention is to improve the quality of the separation of suspensions by reducing the turbulization of the flow of purified liquid at the exit of the rotor; increasing the safety of the process when separating fire and explosive suspensions, ensuring their complete removal when stopping the rotation of the rotor, increasing the performance of the centrifuge in the purified liquid.

This is achieved by the fact that in the proposed centrifuge, the blades are fixed on the rotor disk, while the chamber for collecting and discharging the cleaned liquid is formed by an annular vertical partition mounted on the lower shell and having holes in the lower part, the proportion of the passage section of which is from 1 to 3% of the passage the cross-section of the holes for introducing the suspension in the upper shell of the rotor, and the distance from the disk to the upper edge of the partition has a value of not more than (D ₁ ² -D ₂ ² ) / D ₃ , where D ₁ is the inner diameter of the shells; D ₂ - the outer diameter of the disk; D ₃ - the outer diameter of the annular vertical partitions.

 The drawing shows a centrifuge, a longitudinal section.

 The centrifuge consists of a housing 1 with nozzles 2, 3 and 4, respectively, for introducing the initial suspension, withdrawing purified liquid and sediment, a rotor located on the shaft 5, consisting of two cone-shaped shells 6 and 7 facing one another with large bases. Between the shells a disk 8 is installed, dividing the inner space of the rotor into two parts. Blades 9 are installed on the surface of the disk, providing rotation of the suspension with an angular speed of rotation of the rotor. An annular partition 10 with holes 11 is installed inside the rotor on the lower shell, forming a chamber 12 for collecting and draining the purified liquid through the drain holes 13. A device 14 is located on the centrifuge shaft for moving the lower shell 6 of the rotor along the shaft 5.

In the upper shell 7, holes 15 are made for the input of the initial suspension into the rotor. The centrifuge rotor drive is conventionally not shown. The proportion of the bore of the holes 11 in the partition 10 is from 1 to 3% of the bore of the holes 15 in the upper shell 7. The distance from the disk 8 to the upper edge of the baffle 10 is not more than (D ² ₁ -D ₂ ² ) / D ₃ .

The drawing shows the designation of the characteristic dimensions of the centrifuge rotor: D ₁ is the inner diameter of the shells of the centrifuge rotor; D ₂ - the outer diameter of the disk; D ₃ - the outer diameter of the annular vertical dividing walls.

 The centrifuge operates as follows.

The initial shared suspension through the inlet pipe 2 and the holes 15 enters the rotor, where, under the action of the blades 9 and centrifugal force, the solid phase (sediment) is directed to the inner walls of the rotor, and the suspension goes around the disk 8, rotates 180 ^o and goes to the separation wall 10. The purified liquid through the gap between the disk 8 and the baffle 10, as well as through the holes 11 in the baffle, enters the receiving chamber 12. Next, the purified liquid through the drain holes 13 enters the housing and is discharged from the centrifuge through the pipe 3. The thickened suspension (precipitate) is periodically discharged from the rotor by opening the shells 6 and 7 with a decrease in the rotational speed of the rotor and the axial movement of the lower shell 6 along the shaft.

 An annular vertical partition mounted on the lower shell of the rotor allows to reduce the turbulization of the fluid flow at the exit of the rotor and thus reduce the concentration of the solid phase in the purified liquid. The holes in the lower part of the annular partition provide the outlet of the purified fluid in the direction of fluid movement in the lower part of the rotor, which significantly reduces the formation of vortex flows in the fluid near the inner surface of the lower shell, and also eliminates the deposition of a finely divided solid phase on the surface of the lower shell when the rotor stops. The proportion of the bore of the holes in the baffle is determined by the ratio of the cross-sectional area of the holes in the baffle to the cross-sectional area of the holes located in the upper shell of the rotor. An increase in the proportion of the bore of the openings in the baffle over 3% leads to the appearance of a circulating fluid flow in the lower part of the rotor, which significantly reduces the quality of the separation of the suspension. Reducing the proportion of the bore of the holes below 1% significantly increases the time of the rotor emptying during a planned or emergency stop of the centrifuge drive. The distance between the disk and the partition is selected based on the constancy of the flow characteristics of the liquid through the zones located inside the rotor. At large distances between the disk and the partition due to the occurrence of circulating fluid flows in the lower part of the rotor, the finely dispersed solid phase is captured and gets into the purified liquid, which reduces the quality of suspension separation by 5-8%.

 Using the proposed technical solution allows to increase productivity ~ by 20-30%, the safety and quality of separation of low-concentrated suspensions containing a finely divided crystalline and fibrous solid phase with a particle size of less than 50 microns. The centrifuge was tested in the treatment of industrial and waste water of Polyex OJSC containing microcrystalline cellulose, as well as in the separation of cellulose nitrate suspensions with a solid phase concentration of less than 1% in the initial suspension. The separation quality of the suspensions was more than 90%.

Sources of information
1. Auth. testimonial. USSR 528120, B 04 C 5/12, 1976.

 2. Auth. testimonial. USSR 463334, C 22 V 9/02, 1973.

 3. Auth. testimonial. USSR 1043882, 04 V 1/10, C 22 V 9/02, 1985 - prototype.

Claims (1)

A centrifuge for separating suspensions, including a housing with technological nozzles, a rotor installed in it on the shaft, consisting of two cone-shaped shells facing one another with large bases, the lower of which is located with the possibility of axial movement to discharge the sediment, and the upper one has openings for introducing the suspension, a disk located inside the rotor, dividing its internal space into two parts, and a chamber for collecting and discharging purified liquid located on the lower shell, characterized in that lenas of the blade, while the chamber for collecting and discharging the purified liquid is formed by an annular vertical partition mounted on the lower shell and having holes in the lower part, the proportion of the passage section of which is from 1 to 3% of the passage section of the holes for introducing the suspension in the upper shell of the rotor, the distance from the disk to the upper edge of the partition has a value of not more than
(D ₁ ² -D ₂ ² ) / D ₃ ,
where D ₁ is the inner diameter of the shells;
D ₂ - the outer diameter of the disk;
D ₃ - the outer diameter of the annular vertical partitions.