SU889112A1 - Cyclon - Google Patents

Description

I

The invention relates to devices for purifying gases derived, for example, from metallurgical aggregates, and can be used in the chemical, metallurgical, cement industry, mainly for cleaning highly dusty gases in a mode close to the dew point, or gases containing solid cohesive particles.

Gas cleaning devices are known, including a cylinder-conical body with a tangential inlet and axial exhaust nozzles, a hopper for collecting the collected dust, over which devices are installed in the form of flat washers or hollow cones with an opening along the axis, which reduces the circulation rate and the outflow from the bunker of separated solid particles l and 2.

A cyclone for trapping suspended particles is known, containing a cylindrical-conical body with tangential inlet and axial exhaust nozzles, a dust collector and mounted in the lower part of the cyclone at a dust outlet with a nozzle with a nozzle, the inlet of which is aligned with the cone aperture, and the outlet openings are made in the form of channels directed tangentially from the center to the wall of the housing. Such constructions

10 cyclone provides an increase in cleaning efficiency due to recirculation of the gas stream, the discharge from the hopper; the particles are captured from the hopper by the flow of purified gas 15 for and further, get into the nozzles, twist in the direction of rotation of the main flow and through the outlet openings the channels are directed to the inner side surface of the cyclone core, where they are separated.

However, when working with highly dusty gases, the temperature of which is cobalt in a wide range, close to the dew points or gases containing cohesive solid particles, for example, coming from the copper plant converters, the annular space formed by a fixedly mounted cone-reflector and machines cyclone bodies, although the cyclone operates at a speed close to the critical one: sticking particles settle on the fastening elements of the reflector cone, it is also possible that the annular space is blocked CTBA large-sized inclusions, e.g. grippable sweat com gas converters when loading cold additives. The aim of the invention is to stabilize the operation of the cyclone by avoiding dust plugging the dust outlet. The goal is achieved by the fact that in a cyclone containing a cylindrical-conical body, a tangential inlet and axial exhaust nozzles, a dust collecting bin located at the bottom of the cone with a nozzle and a nozzle with a nozzle, it is equipped with a compressed gas gas outlet the end of which is located inside the cone-reflector and reinforced concentrically on the nozzle with a guide sleeve with a travel stop. FIG. 1 shows a cyclone, a general view5 of FIG. 2 - a cone with a nozzle and a device for moving them. The proposed cyclone contains a cylinder-conical body 1 with a tangential inlet nozzle 2 and an axial exhaust nozzle 3, a dust collector A, a cone-reflector 5 with nozzle 6 rigidly connected to it and made in the form of a cochlea, the inlet of which is aligned with the inlet of the 7. cone 5, and the outlet of 8 is made in the form of channels directed along the tangent from the center to the walls of the housing 1. Inside the cone 5 along its longitudinal axis are installed coaxiallythe sleeve 9 is rigidly and hermetically fixed to the upper part of the nozzle 6, and the gas line 10 fixed to the bunker t The radial clearance of the mea- sure by the sleeve and the output end of the gas line 10 should be minimal to ensure their free movement with account. 4 volume of thermal expansion and exclusion of compressed air losses. To limit the stroke of the cone 5 with the nozzle 6, rings 11 are mounted in the upper part of the pipeline 10, and washer 12 is mounted on the sleeve 9, which cover the radial clearance between the pipes and increase the lifting force when the compressed air is supplied. The distance between the washer 12 and the lower ring 11 determines the height of the raising of the cone with the nozzle. Restricting the lifting of the cone can also be done by other well-known TESTS. The cyclone works as follows. A gas stream with particles suspended in it is introduced through the inlet 2 and is directed downwards in a rotating spiral. The main part of the suspended particles in the gas is thrown against the wall of the housing 1 and, moving, moves towards the annular gap. Peripheral layers, enriched in suspended particles, enter the bunker through the annular slot, where the separation of suspended particles occurs when the direction of movement of the downward part of the flow from the bunker to the exhaust pipe 3 is reversed. There is some fraction of suspended particles from circulation and the blurring effect of vortices in the bunker k is captured by the flow of purified gas and through the holes in the apex of the reflecting cone 5 is carried to nozzle 6. In nozzle 6, the upward flow of gas is twisted in the direction of rotation of the main flow. In this case, the trapped particles are thrown to the peripheral layers of the descending gas flow and sent through the annular gap again into the hopper 4 o. The purified gas flow is removed from the cyclone through the exhaust pipe 3. At certain intervals, depending on the characteristics of the dust-gas flow and the mode of operation of the cyclone gas pipeline 10 serves pulses of compressed gas; gas, hitting the upper end of the nozzle 6, raises the cone, 5 with the nozzle 6 up, while the cone 5 under the influence of the reactive moment is secondary; the flow of gas to be cleaned through the channels of the nozzle 6 and the centrifugal forces of the axial flow rotates around its longitudinal axis, while settled on the surface

the dust cone is removed and easily enters the hopper C through an enlarged annulus. When the supply of compressed gas to the pipeline 10 is stopped, the cone with the nozzle abruptly returns to its original position, i.e. Sadits on the output end of the pipeline 10, with the additional shaking of dust.

A cone reflector capable of moving along the longitudinal axis ensures stable operation of the cyclone, excluding the overgrowth of the annular space caught by dust. . The cyclones of the proposed design provide a constant dust collection efficiency of up to 90.

Claims (3)

1. USSR author's certificate K-k2nk2, cl. On C 11/00, 1972 2. US patent IP 3988133, Kn.SS-fSS, 197. 3. US patent W 3590558, class 55-338, 1971 (prototype) ..