RU2007230C1 - Separator - Google Patents

Abstract

FIELD: separation technology. SUBSTANCE: separator has a case, cylindrical guide device 6 with plates which is mounted in the case, a drive shaft with rotor 7, positioned inside guide device 6, unload and load branch pipes 12 and 13 respectively. Plates are mounted in series along the length of guide device 6 and are made rotatable. Each plate is mounted at a differentiated angle of inclination along the perimeter and the length of guide device 6. EFFECT: improved structure. 3 dwg

Description

 The invention relates to techniques for the separation of grinding products after grinding various solid materials and can find application in the construction, chemical, mining and other industries related to grinding and classification of grinding products.

 Known centrifugal classifier, comprising a housing, a rotor with radial separation channels expanding to the axis of the rotor, and overflow shelves. In this case, the rotor is placed horizontally on the hollow drive shaft. The classifier also contains nozzles for supplying air and source material, an axial nozzle for removing the fine fraction, communicated through holes in the hollow shaft with separation channels, a nozzle for collecting large fractions.

 In addition, the housing is equipped with partitions perpendicular to the axis of the hollow shaft and dividing the housing into chambers. The rotor is made in the form of an impeller with radial blades mounted on the shaft in several rows, each of which is installed in a corresponding chamber, and a separation channel is made in each radial blade, and passage chambers are connected to each other on the periphery of the partitions with overlapping shutters installed with the ability to change the angle of inclination to the partitions.

 The disadvantages of the known separator include the low efficiency of the classification process.

 The closest technical solution known is the separator, which includes a cylindrical-conical body with loading and unloading nozzles. Inside the cylindrical part of the casing there is a separation chamber consisting of a guide device with plates uniformly mounted around its circumference, and a drive shaft with a rotor, which is placed coaxially, inside the guide device.

 The disadvantages of the known separator are the low efficiency of the separation process, arising from the fact that large particles of material in a highly dusty stream during deposition capture a large amount of small finished product; design complexity and significant energy consumption caused by vertical material transportation.

 The purpose of the invention is to increase the efficiency of separation of the material, the reliability of the structure, simplifying it, reducing energy consumption.

 The essence of the invention lies in the fact that in the known separator comprising a housing, a cylindrical guide device fixed therein with plates uniformly mounted around its circumference, a drive shaft with a rotor that is coaxially placed inside the guide device, loading and unloading nozzles, and the guide device plates installed sequentially along its length and made rotary, with each plate installed at a differentiated angle of inclination around the perimeter of circularity and length of the guide device.

 Distinctive features from the prototype are the fact that the plates of the guide device are installed sequentially along its length and are rotatable, with each plate installed at a differentiated angle of inclination along the circumference and the length of the guide device.

 In FIG. 1 is a schematic representation of a separator; in FIG. 2 is a section AA in FIG. 1; in FIG. 3 is a section BB in FIG. 1.

 The separator contains a housing consisting of a cylindrical 1 and conical 2 parts. The inlet part of the separator is made in the form of a "snail", which has two inlet pipes 3 and 4. The pipes 3 and 4 are designed to supply aspiration air with the supplied material. In addition, the cylindrical part 1 of the housing has a discharge pipe 5 for the exit of air with the finished product.

 Inside the cylindrical part 1 of the casing, a guide device 6 is horizontally arranged, consisting of a fixed frame with plates that are mounted on the axles uniformly around the circumference and sequentially along the length of the guide device 6 and are rotatable, each plate being installed at a differentiated angle of inclination around the circumference and length guide device 6. In this case, the cylindrical part 1 of the housing and the guide device 6 form an “external contour”.

 Inside the guide device 6, a rotor 7 is coaxially placed, which has blades along the generatrix and is mounted horizontally on the drive shaft 8 on two outriggers 9.

 The guide device 6 and the rotor 7 form a "inner loop" - a separation zone 10, which is frontal along the material is limited by the wall 11, which prevents the material from entering the zone 10 and the rotor 7 directly from the supply pipe 3.

 The conical 2 part of the housing has nozzles 12 for supplying secondary (tertiary) air and a discharge nozzle 13 for unloading the grains.

 The device operates as follows.

 The material arriving after the mill in the separator loading device is picked up by aspiration air and through the inlet "snail" enters the external circuit. Here, centrifugal, centripetal, and gravitational forces act on particles of material.

 Centrifugal forces are created due to the fact that structurally the entrance to the separator is made in the form of a "cochlea", and centripetal forces are due to the fan traction (not shown in Fig. 1-3).

 Having passed the "external contour", the particles of material through the guide device 6 fall into the "internal contour", that is, into the separation zone 10 of the cylindrical 1 part of the body, where centrifugal, centripetal and gravitational forces also act on the particles. The effective classification of the material is due to a certain mutual combination of these forces.

 Small particles (finished product) enters the rotor 7 and is carried out through the pipe 5 by aspiration air.

 Large fractions are discarded by centrifugal forces on the plates of the guiding device 6 and, under the influence of gravitational forces, flow down into the conical 2 part of the body.

 Through the nozzles 12, tertiary air is supplied to the conical 2 part of the housing for additional separation of the finished product carried away by large fractions, after which the grains are discharged from the separator through the nozzle 13.

 The present invention improves the efficiency of material separation, reliability, and also reduces energy consumption and laboriousness in the manufacture of the separator. (56) Copyright certificate of the USSR N 1214249, cl. B 07 B 7/08, 1984.

 Article Deynat G., Bartrand I. I. L'ame'liration du rendment des ate liere de broyage Cements Betons. Platres, chaux, 1985, N 754, p. 164 (France) - prototype.

Claims (1)

 SEPARATOR, comprising a housing, a cylindrical guiding device fixed in the housing with plates evenly spaced around its circumference, a drive shaft with a rotor coaxially placed inside the guiding device, loading and unloading nozzles, characterized in that, in order to increase the separation efficiency, the plates are installed in series along the length of the guide device and are made rotatable, with each plate mounted at a differentiated angle of inclination around the perimeter of the zhnosti and the length of the guiding device.

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