RU84747U1 - CENTRIFUGAL CLASSIFIER - Google Patents

Abstract

A centrifugal classifier containing cylinder-conical inner and outer housings with covers, a finished product outlet pipe located on the outer case cover and a large product outlet pipe of the outer and inner buildings, a source material supply pipe located at the bottom of the outer case, twisting blades located between the cylindrical parts of the outer and inner shells, characterized in that a shell is mounted above the twisting vanes, between which and the outer shell m radially placed zigzag plates.

Description

The utility model relates to devices for separating bulk materials into small and large products and can be used in heat power, electrode and other industries.

Known centrifugal classifier containing cylindrical inner and outer shells, the outer shell cover with a pipe outlet of the finished product and the branch pipe of the large products of the outer and inner shells, the supply pipe of the starting material, twisting blades located between the cover of the outer shell and the upper generatrix of the inner shell / 1 / .

The design disadvantages are the low classification efficiency due to the cyclone separation principle, when there is no strictly opposite direction of the aerodynamic and centrifugal forces acting on the particle.

The closest in technical essence and the achieved effect to the claimed one is a centrifugal classifier containing cylindrical conical inner and outer casings, with covers, outlet pipe of the finished product, placed on the cover of the outer casings and branch pipes of the large product of the outer and inner casings, pipe for supplying the starting material, located in the lower part of the outer casing, swirl vanes located between the cylindrical parts of the outer and inner casings / 2 /.

In the classifier, an increase in separation efficiency is achieved, since the covers of the bodies form a flat centrifugal-countercurrent classification zone with the strictly opposite direction of centrifugal and aerodynamic forces.

The design disadvantages are low classification efficiency due to the fact that large particles in the classification zone under the influence of the prevailing centrifugal forces fall on the wall of the outer casing, slide down and are discharged through the branch pipe of a large product, while they capture some of the small particles, which reduces the classification efficiency .

The purpose of the utility model is to increase the classification efficiency.

This goal is achieved by the fact that in a centrifugal classifier containing cylindrical conical inner and outer shells, with caps, a pipe for the outlet of the finished product, located on the cover of the outer shell and a branch pipe for the removal of a large product of the outer and inner shells, a pipe for supplying the starting material, located in the lower part of the outer housings, spinning blades located between the cylindrical parts of the outer and inner cases, a shell is installed above the spinning blades, between which th and the outer casing radially arranged zigzag plate.

A distinctive feature, namely: the installation of a shell over the twisting blades of the shell, between which the outer case and zigzag plates are radially placed, leads to the emergence of a new property - winding large material sliding on the wall of the outer case and isolating small particles from it, which ensures the achievement of the goal - increasing classification efficiency.

Figure 1 presents a centrifugal classifier, a longitudinal section; figure 2 is a section along aa in figure 1; figure 3 - comparison of experimental data on the separation curves of the known and proposed classifiers.

The centrifugal classifier consists of an outer casing 1 with a cover 2, outlet pipes for finished 3 and large 4 products and a supply pipe for starting material 5, an inner case 6 with a cover 7 and a branch pipe for large product 8. Spinning vanes 9 are located between the cylindrical parts of the outer and inner bodies over which the shell is placed 10. Between the outer casing 1 and the shell 10 are radially mounted zigzag plates 11.

Centrifugal classifier works as follows. The source material together with the conveying air is fed through the pipe 5 into the channel formed by the conical parts of the outer 1 and inner 6 buildings. Some of the largest particles fall out of the stream and are discharged through the nozzle of the large product 4. The bulk of the material, due to a change in the direction of flow, moves along the wall of the inner casing 6 and enters into the swirl vanes 9. The swirling flow enters the flat centrifugal countercurrent classification zone formed by the outer cover 2 housing and cover 7 of the inner housing. Under the influence of the prevailing aerodynamic forces, small particles move to the center of the classification zone and are discharged through the pipe 3 into the finished product. Part of the large particles falls out of the flow in the classification zone, passes through the gap between the cover 7 and the cylindrical part of the inner case 6, slides along the inner wall of the inner case 6 and is discharged through the branch pipe of the large product 8. The bulk of the large particles under the influence of the prevailing centrifugal forces move to the periphery of the zone and fall on the wall of the outer casing, while large particles capture with them part of the small particles. Sliding along the inner surface of the outer casing, large particles with trapped small particles enter the channels formed by zigzag plates 11 placed radially between the shell 10 and the outer casing 1, where they fall into the upward flow of conveying air supplied with the source material, due to which the fine particles are winnowed captured by large ones and returning them to the classification zone. The sown large particles slide along the wall of the outer casing and are discharged through the pipe 8 into a large product.

Comparison of the separation curves of the classifier - a known and proposed object - made in bench conditions on models with a diameter of 400 mm, shows the possibility of increasing the separation efficiency by installing a shell over twisting blades with a zigzag plate placed radially between it and the outer case. Since the efficiency (η) increases from 0.78 to 0.83, the degree of breakthrough of large particles into a small product (ε) decreases from 0.41 to 0.38.

Thus, the proposed utility model improves the classification efficiency.

Sources of information taken into account when preparing the application:

1. Lebedev A.N. Preparation and grinding of fuel at power plants, M., "Energy", 1969, Fig. 11-12.

2. Copyright certificate of the USSR No. 899165, cl. B07B 7 / 08.1980.

Claims (1)

A centrifugal classifier containing cylinder-conical inner and outer housings with covers, a finished product outlet pipe located on the outer case cover and a large product outlet pipe of the outer and inner buildings, a source material supply pipe located at the bottom of the outer case, twisting blades located between the cylindrical parts of the outer and inner shells, characterized in that a shell is mounted above the twisting vanes, between which and the outer shell m radially placed zigzag plates.