SU1599101A1 - Hydrocyclone - Google Patents

Abstract

The invention relates to a device for the separation of granular materials by size in a liquid medium and can be used to classify ore slurries in nonferrous metallurgy. The goal is to increase the efficiency and effectiveness of the classification process. The hydrocyclone consists of a cylindrical housing 1, a tangential inlet 2, a drain nozzle 3 with a drain nozzle 4, and an exponential sand nozzle 5 made of solositall. The original slurry under pressure enters the housing 1 through the nozzle 4 and twists. Small particles are discharged from the central zone of the apparatus through the drain nozzle 3 and nozzle 4, and the large particles are discharged through the sand nozzle 5. The use of the exponential nozzle 5 reduces the vortex formation on its surface, and the use of solositall significantly increases its wear resistance. 1 ill., 1 tab.

Description

The invention relates to a device for separating granular materials by size in a liquid medium and can be used in non-ferrous and ferrous metallurgy, chemical and construction industries

The aim of the invention is to increase the efficiency and economy of classification. 10

The drawing schematically shows the proposed hydrocyclone, section. The hydrocyclone consists of a cylindrical body 1 installed tangentially to the cylindrical part of the inlet pipe 2, introduced through the cover of the drain nozzle 3 with a drain pipe 4 adjoining to it from above and mounted on the lower end of the conical part of the exponential sand nozzle ~ 20 ki 5 made of ash-metal.

Hydrocyclone works as follows.

The initial pulp under excess pressure is fed through the tangential 25 inlet pipe 2 into the cylindrical part of the housing 1, where it acquires a rotational movement. In this case, small particles move to the central zone and are discharged through the drain nozzle 3 and nozzle 4. Large particles, under the action of the centrifugal force field, are concentrated in the wall layer, are displaced downward and are discharged through the sand nozzle 5. · - · _

The implementation of the sand nozzle with a longitudinal section profile in the form of an exponent increases its wear resistance due to a smoother flow around the pulp and contributes to a more efficient separation of fines due to a sharp increase in the peripheral speed of the pulp and a decrease in hydraulic resistance, caused, in turn, by a decrease in the height of the nozzle by 2 3 times and preventing the formation of large-scale vortices in the lower part of the hydrocyclone, which significantly move the separation products. The wear resistance of the sand nozzle is also increased due to its implementation from ash-metal. Ultimately, the used technical solutions provide an increase in the efficiency and economy of the classification.

The hydrocyclone of the proposed design was tested in comparison with the prototype in an industrial environment. The tests were carried out with sand nozzles with linear, parabolic and exponential cross-sectional profiles, the performance of the compared hydrocyclones depending on the profile and material of the sand nozzles, as well as the pulp pressure at the inlet was estimated by the results of sieve analyzes of products, classification products and the amount of wear of the nozzles. The test results are shown in the table.

The data presented in the table show that the highest classification indices were obtained using a sand nozzle in the form of expotenta of the form y = -y + 2 exp2h. A decrease or increase in the coefficients in the exponential part of the equation leads to a decrease in the classification efficiency due to a violation of the smoothness of the pulp flow around the nozzle inner surface and the formation of large-scale vortices. Of the tested materials, the most wear-resistant is30.

Claims (1)

Claim A hydrocyclone, including a cilihydroconic housing, a tangential inlet pipe, a drain pipe, a coaxial drain and sand nozzles, which is different from, p. In order to increase the efficiency and economy of classification, the sand nozzle is made with a longitudinal section profile in the form of an exponent of the form ι Y = 4d · + 2 exp 2 h, where y is the distance from the axis of the hydrocyclone to the inner surface of the sand nozzle; cl _n is the minimum diameter of the sand nozzle; h is the height of the sand nozzle in the calculated section, and the body of the nozzle is made of ash-metal. Type of nozzle carrier Hydraulic inlet pressure Nozzle material cyclone, atp -----------1 0.5 1,0 1,5 Steel 45 Stone casting Zolosi tall Time to increase the diameter of the hole by 1 mm, h Classification efficiency -0.074 mm, '% 1. Conical with a taper angle, d: (basic) d ~ 20 ° 31,4 32,7 35.1 4 12 600 d = 45 * 32,7 33.6 35,4 4 12 600 ¢ / = 60 ^d 32,5 33,4 36.5 4 12 600 d = 90 ^e 30.1 31,4 31.7 4 12 600 Parabolic: y = 4j- +. aH ^h (prototype) a = 0.5; n = 2 33.7 34.6 35.8 4 · 12 600 a = 1.0; η = 2 33.5 34.9 36.1 4 12 600 a = 2.0; η = 2 32.3, 34.8 37.1 4 12 600 a = 0.5; η = 3 33,4 33.6 34.9 4 12 600 a = 1, 0; η = 3 34.2 35.9 36.7 4 12 600 a = 2.0; n = 3 34.1 36,2 36.9 4 12 600 Exponential: Y = -y + a exp Hb gay) a = 0.5; b = 1 33.5 31,4 37.5 12 24 720-800 a = 1.0; b = 1 33,4 36.3 37.9 12 24 720-800 a = 2.0; b = 1 33,4 35.7 37.3 12 24 720-800 a = 3.0; b = 1 • 35.7 36,4 38,4 12 24 720-800 a = 0.5; b = 2 34.2 36.1 39.5 12 24 720-800 a = 1.0; b = 2 35.8 47.8 47.9 12 24 720-800 a = 2.0; B = 2 40,0 51, 0 58.0 12 24 720-800 a = 3.0; b = 2 38,4 47.6 48.1 12 24 720-800 a = 0.5; b = 3 38.5 41, 4 42,4 12 24 720-800 a = 1.0; b = 3 39,4 42.1 41.7 12 24 720-800 a = 2.0; b = 3 37.1 39.6 41.8 12 24 720-800 a = 3.0; b = 3 35,4 37.1 41,4 12 24 720-800