RU2171720C2 - Swirl-acoustic classifier - Google Patents

Abstract

FIELD: equipment for separation of finely dispersed materials; applicable in manufacture of building materials, mining, chemical electric power and other industries. SUBSTANCE: classifier includes body with semitore surface in upper part; truncated cones turned with their large bases upward and located under semitore surface and entering one another in height; loading branch pipe located tangentially to lower truncated cone; discharging appliances. Small bases of truncated cones are located at some angle to horizontal axis which coincides with material angle of repose. Cones are secured with their small bases to each next cone. Installed inside semitore surface, fastened to upper truncated cone, is toroidal settler conjugated with semitore surface and having discharge branch pipes located in its lower part. Settler is connected by means of corrugated branch pipes, secured in its upper part with cone-shaped cloth dust collector installed in metal body located inside truncated cones. Lower part of cloth dust collector has discharge branch pipe coaxially installed relative to discharge branch pipe of lower cone. Relation between diameters of tore and corrugated branch pipes is d= (0.05-0.15)D, where d is diameter of corrugated branch pipe; D is diameter of tore settler. EFFECT: higher efficiency of material classification with different mechanical and physical characteristics. 3 cl, 3 dwg

Description

 The invention relates to techniques for the separation of fine materials and can be used in various industries of building materials, as well as mining, chemical, energy and other industries.

 Various constructions of classifiers are known, including pneumomechanical ones, which ensure the separation of finely ground powders into fractions using air flows and using various mechanical devices (ed. St. 404519 A, B 07 B 4/08, B.I. N 44, 1973; ed St. 418226 A, B 07 B 4/08, B.I. N 9, 1974).

 The disadvantages of these classifiers are: low separation efficiency and increased energy consumption for the classification process.

 The closest technical solution to the proposed one is a classifier that includes a housing, the upper part of which is made in the form of one and a half, with a separating surface located inside it, overflow shelves, loading and unloading devices (SU 891179 A, 12/23/1981, B 07 B 4/04) .

 The disadvantages of the classifier are: low efficiency of the separation of the finely dispersed mixture into fractions, as well as the lack of the ability to control the degree of classification in the apparatus.

 The invention is aimed at improving the classification efficiency by increasing the trajectory of the dusty mixture, and expanding the functionality of the device.

This is achieved by the fact that in the classifier, which includes a housing with a half surface in the upper part and truncated cones located one above the other in one and a half surface each other in height, turned upside down by large bases, a loading nozzle located tangentially to the lower truncated cone, unloading devices, according to the proposed solution, the smaller base of the truncated cones are made at an angle to the horizontal axis, coinciding with the angle of repose of the material, and the cones are smaller the bases are fixed on each subsequent cone, forming gutter-like channels passing into discharge nozzles, inside the one and a half surface mounted on the upper truncated cone, a toroidal precipitator mating with it is installed, with discharge nozzles located in its lower part, connected by means of securing in its lower part corrugated nozzles with a cone-shaped cloth dust collector installed in a metal housing located inside the truncated cones, while in the lower part of the erchatogo dust collector is unloading pipe, the diameter ratio of the torus and corrugated pipes is
d _g.p = (0.05-0.15) D _m ,
where d _gn - diameter of the corrugated pipe;
D _m - diameter of the torus precipitator,
and at the top of the metal housing of the dust collector there is a rotor in the form of an impeller with blades and a snail on which the electric drive is mounted, a loading nozzle is installed with the possibility of changing the angle α to the vertical axis of the classifier within α = 45 - 70 ^o .

To eliminate additional resistance to air flow, the inlet direction of the loading nozzle can be opposite to the directions of the corrugated nozzles entering the fabric dust collector, and to ensure the acoustic effect, the ratio of the diameters of the torus precipitator and the corrugated nozzles should be
d _g.p = (0.05-0.15) D _m ,
where d _gn - diameter of the corrugated pipe;
D _m - diameter of the torus precipitator.

 To exclude additional resistance of the air mixture rising upward along the spiral, the angles of inclination of the truncated cones and the housing of the dust collector coincide.

The use of this invention provides the achievement of new properties, namely:
1. In improving the classification efficiency of materials with different physical and mechanical characteristics (particle size distribution, density, aerodynamic properties, etc.) in a wide range of fractional composition (10 - 100 microns).

 2. The possibility of using this apparatus for various functional values: as a separator (with open discharge pipes), as a cyclone - bag filter (with closed discharge pipes).

 3. In ensuring efficient continuous regeneration of the filter cloth of the fabric dust collector through the use of the acoustic effect created by the passage of air under pressure through the corrugated pipes.

 4. In a high degree of purification (η≥98%) of the aspirated air leaving the apparatus (due to the use of various technical methods: the ability to remove particles in the direction of their movement and reduce their flight speed, the possibility of damping the speed of particles in a toroidal precipitator when changing direction rotation of the air flow, in the possibility of efficient regeneration of the filter cloth, as well as the possibility of varying the aerodynamic parameters of the classifier when changing its geometric parameters - height, area section).

Comparative analysis with the prototype shows that the claimed vortex-acoustic classifier is characterized in that the smaller bases of the truncated cones are made at an angle to the horizontal axis, coinciding with the angle of repose of the material. The cones with smaller bases are fixed on each subsequent cone, forming gutter-like channels passing into the discharge pipes. Inside the one and a half surface mounted on the upper truncated cone, a toroidal precipitator mated with it is connected by means of corrugated pipes fixed to its upper part with a conical cloth dust collector installed in a metal case located inside the truncated cones. An unloading nozzle is integrated in the lower part of the fabric dust collector. The ratio of the diameter of the torus and corrugated pipes is
d _g.p = (0.05-0.15) D _m ,
where d _gn - diameter of the corrugated pipe;
D _m - diameter of the torus precipitator.

At the top of the metal housing of the dust collector is a rotor in the form of an impeller with blades and a snail on which the electric drive is fixed. The loading nozzle is tangentially integrated into the lower truncated cone with the possibility of changing the angle α to the vertical axis of the classifier within α = 45 - 70 ^o . In the lower part of the toroidal precipitator discharge nozzles are located. The direction of entry of the loading pipe may be opposite to the direction of entry of the corrugated pipes into the fabric dust collector. To exclude additional resistance of the air mixture rising upward along the spiral, the angles of inclination of the truncated cones and the housing of the dust collector coincide.

 Thus, the inventive separator meets the criteria of the invention of "novelty."

In the study of other well-known technical solutions in this technical field, distinctive signs from the prototype were not detected, in addition, with their help, the claimed classifier acquires new properties, consisting in:
a) various functional purposes: cyclone - bag filter, separator;
b) the possibility of damping the velocity of particles in a toroidal precipitator;
c) the possibility of varying the aerodynamic parameters of the classifier when changing its geometric parameters.

 In FIG. 1 shows a General view of the proposed vortex-acoustic classifier.

 In FIG. 2 - section aa.

 In FIG. 3 - section BB.

 The classifier consists of a housing 1 with one and a half surface 2 in the upper part, loading 3 and unloading 4, 5, 6, 11 nozzles; cone-shaped cloth dust collector 7, enclosed in a metal housing 8. In the upper part of the classifier installed torus precipitator 9, connected using corrugated pipes 10 with a cloth dust collector 7 (Fig. 1). In the lower part of the torus precipitator discharge pipes 11 are installed (Fig. 1). Corrugated pipes enter tangentially into the fabric dust collector (Fig. 3).

 The fabric dust collector in its upper part is in contact with the cochlea 12, inside of which a rotor 13 in the form of an impeller with blades is fixed above the end surface of the dust collector. An electric drive 14 of the rotor is fixed on the cochlea.

The original air mixture flows tangentially into the lower truncated housing through the inlet pipe 3, which, if necessary, allows you to vary the angle of supply of the mixture in the range α = 45-70 ^o to the vertical axis (Fig. 1).

If this condition is not met, either the air mixture flows into the upper part of the classifier (at α <45 ^o ), or (at α> 70 ^o ) - a significant frontal resistance from the walls of the housing, which impairs the classification of the mixture particles.

 Rising in a spiral along an ascending line, the particles of the mixture are pressed under the action of centrifugal force to the inner surface of the truncated cones, and losing their speed, due to the increasing cross-section of the classifier, fall into the grooved channels and are discharged through the discharge pipes 5. The largest discharge pipes 4 are removed particles through the upper pipe 5 - the smallest particles. The degree of classification of the mixture can be adjusted by changing the angle of supply of the material α and due to air pressure.

To ensure free flow of particles through the discharge pipes 4, 5, the angle of inclination to the vertical axis must coincide with the angle of repose of the material and can be β = 30-45 ^o . If the conditions are not met, the process of spontaneous discharge of particles is difficult.

 In the upper part of the classifier, fine particles through spiral channels enter a toroidal precipitator 9, in which part of the particles, due to a change in the direction of rotation of the flow, settles to the bottom of the toroidal precipitator, and the rest with air flow is sent through corrugated tubes 10 to a cloth dust collector 7. Unloading settled particles of material is carried out through the discharge nozzles 11 (Fig. 1).

 Corrugated pipes are fixed in the upper part of the toroidal precipitator and enter the fabric dust collector, creating a whirlwind flow. The use of corrugated pipes with a sufficiently powerful air flow provides an acoustic effect in the dust collector (sound waves), which contribute to the continuous regeneration of the fabric filter of the dust collector.

 To eliminate additional resistance to air flow, the direction of entry of the corrugated nozzles 10 into the cloth dust collector 7 can be made along a helix opposite the direction of entry of dusty air through the loading nozzle 3 (Fig. 3).

To ensure the acoustic effect, the ratio of the diameters of the corrugated pipes 10 and the diameter of the toroidal precipitator 9 must be strictly defined
d _g.p = (0.05-0.15) D _m ,
where d _gn - diameter of the corrugated pipe;
D _m - diameter of the torus precipitator.

If these conditions are not _met , either an increased resistance to air flow is observed (with d _gn <0.05D _m ), and therefore, the passage of air into the dust collector is hindered, or conditions (with d _gn > 0.15 D _m ) are _worsened the appearance of the acoustic effect (the appearance of resonant frequencies).

 Caught the thinnest particles are discharged from the classifier through the discharge pipe 6, as well as discharge pipes 11 located in the lower part of the toroidal precipitator.

 The filter cloth of the cloth dust collector is fixed, for example, to the mesh frame of the metal housing 8.

 To ensure the removal of purified air along the path in the upper part of the cloth dust collector, above its end surface, a rotor 13 is installed in the form of an impeller with blades, which is located in the cochlea 12 (Fig. 1, 2). The rotation of the rotor is carried out by means of an electric drive 14 mounted on a cochlea.

 To exclude additional resistance of the air mixture rising upward along the spiral, the angles of inclination of the truncated cones and the dust collector body coincide with each other.

 Thus, the vortex-acoustic classifier, using a rather elongated trajectory of the dust-air flow, as well as the acoustic effect for the continuous regeneration of the fabric of the dust collector, provides an increased classification of the dust-like mixture throughout its path of movement.

Claims (3)

1. Classifier, comprising a housing with a half surface in the upper part and truncated cones located one above the other and one and a half in height, turned upside down by large bases, a loading nozzle located tangentially to the lower truncated cone, unloading devices, characterized in that the smaller bases truncated cones are made at an angle to the horizontal axis, coinciding with the angle of repose of the material, with cones with smaller bases fixed to each The following cone, forming gutter-like channels passing into discharge nozzles, has a toroidal precipitator mated to it and discharge nozzles located in its lower part and connected with a cone-shaped corrugated pipe fixed in its upper part inside a one and a half surface fixed to the upper truncated cone a fabric dust collector installed in a metal housing located inside the truncated cones, while at the bottom of the fabric dust collector ygruzochny pipe, the diameter ratio of the torus and corrugated pipes is
d _g.p = (0.05 - 0.15) D _t ,
where d _gn - diameter of the corrugated pipe; D _t - the diameter of the torus precipitator,
and at the top of the metal housing of the dust collector there is a rotor in the form of an impeller with blades and a snail on which the electric drive is fixed, a loading nozzle is installed with the possibility of changing the angle α to the vertical axis of the classifier in the range: α = 45 - 70 ^o .  2. The classifier according to claim 1, characterized in that the direction of entry of the loading nozzle is opposite to the directions of entry of the corrugated nozzles into the fabric dust collector.  3. The classifier according to claim 1, characterized in that the angles of inclination of the truncated cones and the dust collector body coincide with each other.

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