SU544470A1 - Centrifuge for separating coarse suspensions - Google Patents

Description

one

The invention relates to the field of dehydration of coarse-grained suspensions and can be used in chemical, food and other sectors of the national household.

Centrifuges for dewatering such products are known, comprising a rotor consisting of a series of conical breaker rings, a receiving sieve, a housing, chambers for receiving a centrate and a solid phase and a feeder.

A known centrifuge for separating suspensions, the rotor of which consists of individual conical breaker rings, between which slots are provided for withdrawing the centrifuge, and between the upper breakaway ring and the wall of the housing there is an annular gap necessary to ensure the rotation of the rotor. The solid-state receiving chamber is cylindrical and located above the upper break-away ring.

However, in such a centrifuge, small solid particles enter the annular gap during the dewatering process and prevent the rotor from rotating freely. When a significant amount of fines get into the annular gap at the same time, the rotor can become jammed, and a portion of the solid phase gets into the fugate.

In the process of moving the solid phase to the discharge nozzle, its particles are in direct contact with the rotor surface, which in turn leads to grinding of the product.

In addition, in the centrifuge, the solid particles under the action of inertial forces move along the rotor with a significant lag, resulting in a decrease in the impact force of the solid particle on the tipping ring, which leads to an increase in the residual moisture of the product, i.e., a decrease in the efficiency of suspension dewatering.

In order to increase the efficiency of separation of suspensions in the proposed centrifuge, the chamber for receiving the solid phase is located under the upper breakdown ring of the rotor and has a spiral bottom with a board installed to form an end gap between it and the upper breaker ring, which has ventilation blades for creating an annular air flow. , and a slurry spreader is installed in the receiving sieve. At the same time, the ventilation blades are fixed at an acute angle to the plane perpendicular to the rotor axis in the direction of rotation of the rotor.

FIG. 1 - the proposed centrifuge, a general view in section; in fig. 2 - the node of the upper burglar ring and the spiral bottom; in fig. 3 is a view along arrow A in FIG. 2; in fig. 4 - plate spider.

The centrifuge consists of: a rotor 1 with conical otoichny rings 2, between which slots 3 are formed; receiving screen 4; housing 5; chambers 6 with bottom 7 in the form of a helical surface for receiving a solid phase; chambers 8 for receiving fugate; drive 9; the feeder 10 and the device 11 for unwinding the suspension.

The bottom 7 of the chamber 6 has a bead 12. Between the side 12 and the flange 13 of the upper baffle ring 2, an end gap 14 is formed.

In the lid 15 of the centrifuge, windows 16 are made for air suction with a retaining net 17 located in them. On the inner side of the lid 15 there is fixed a conical element 18 for providing directional air movement.

In order to create an annular air flow in the chamber 6, the ventilation blades 19 are fixed on the upper breaking ring of the rotor. The latter are fixed at an angle a less than 90 ° to the surface of the flange 13 in the direction of the rotor.

The device 11 for unwinding the suspension can be made removable in the form of a lamellar cross. At the same time, its attachment to the receiving situation 4 can be accomplished with the help of intermediate sleeves 20 and clamping bolts 21. This will allow to install crosses of various shapes and thereby select the optimum circumferential speed of solid particles.

The centrifuge works as follows.

The suspension to be separated is fed through a feeder 10 into a receiving sieve 4, where the bulk of the liquid is separated. The solid particles are captured by the device I’s cross, acquiring a circumferential speed equal to or close to the rotor 1’s circumferential speed, and are ejected due to inertial forces to the fender rings 2. The final dewatering of the solid particles occurs at the fender rings, and the centrifugal force is consumed only on the impact and the solid particle movement along the generatrix of the conical rings, since the lag in the rotation of the particles from the rotor is insignificant. The separated liquid due to the adhesion forces and centroOne forces flows down with a thin film in the gap 3 between the baffle rings 2.

The dehydrated solids under the action of centrifugal forces enter the chamber 6, where they are picked up by a vortex annular air flow created by the ventilation blades 19 and in a spiral

bottom surfaces of the 7 pins out of the centrifuge

through the tangential pipe (in the drawings

not shown). With this air feed

through windows 16.

Particulate matter of any size

moving along the spiral surface of the bottom 7 of the chamber 6, into the end gap 14 between the edge 12 of the chamber bottom and the flange 13 of the upper breakdown ring 2 is prevented. As a result of centrifugal forces (in case of contact with the rotating fender ring 2) and the vertical component of the air flow from the ventilation blade 19, the particles are dropped from the end gap and move along the spiral surface of the chamber bottom towards the discharge side.

Claims (2)

1. A centrifuge for separating coarse-grained suspensions, comprising a rotor consisting of a series of conical break-away rings, a housing with chambers for receiving a centrate and a solid phase, and a receiving sieve, characterized in that, in order to increase the efficiency of separation of suspensions, the chamber for receiving The solid phase is located under the upper rotor breakdown ring and has a spiral bottom with a side mounted to form an end gap between it and the upper breakdown ring, on which the ventilation blades are fixed to create an annular air flow, and a suspension spinning device is installed in the receiving strip. 2. A centrifuge according to claim 1, characterized in that the ventilation blades are fixed at an acute angle to the plane perpendicular to the axis of the rotor in the direction of rotation of the rotor. 15 IB l , l, / i, / -r W u / / / l H-fl h . lg.g ftjdA / fS (Riga.Z