UA71554U - Lining of cylindrical section of hydraulic cyclone - Google Patents

Abstract

A lining of a cylindrical section of a hydraulic cyclone is made of rubber or other durable material in the form of a cylinder. The lining flanges have triangular protrusions located from the outside of the flange.

Description

A useful model belongs to the field of mineral enrichment, in particular to hydrocyclones, in which the body sections are equipped with wear-resistant linings, and can be used in mining, metallurgy, chemical, pulp and paper, construction and other industries for the separation of solid phase particles in a liquid stream, revolving.

It is known that a hydrocyclone is a device of continuous action, which is used in a technological chain, for example, mining and beneficiation, and is intended for size separation of materials suspended in a liquid medium - pulp or suspension (further pulp).

Structurally, a hydrocyclone includes a body consisting of an upper, usually cylindrical, inlet section with a tangential feed nozzle, which is also called the inlet head, a cover and several conical sections that taper downwards, a drain nozzle installed along the axis of the cover, and a sand nozzle. attached to the lower conical section of the hydrocyclone body.

The operation of the hydrocyclone is based on the action of centrifugal forces on the solid particles suspended in the pulp, which continuously moves along a spiral inside, mostly sectional, the casing, which tapers downwards.

Under the action of centrifugal forces, solid particles of a larger (heavy) fraction are thrown to the periphery, lose speed due to frictional forces, fall down the wall of the casing and are removed from the hydrocyclone through the sand nozzle.

At the same time, small solid particles of the fine (light) fraction, suspended in the liquid medium, clarified pulp along the axis of the cyclone, where a zone of reduced pressure is formed, are removed from the hydrocyclone by an upward flow through the drain pipe located in its cover.

To protect the constituent parts of the hydrocyclone from abrasive wear, their walls in contact with the pulp are covered with replaceable wear-resistant elements - linings made of wear-resistant materials, among which rubber is the most common.

In the cylindrical section, the separation of heavy and light particles, which are in the pulp, begins.

As a result of the fact that in this part of the hydrocyclone the transformation of the laminar pulp flow into a vortex continues, the cylindrical section of the hydrocyclone interacts with solid materials,

It is suspended in the pulp and is subject to intense abrasive wear. To protect the cylindrical section of the hydrocyclone, it is protected by a replaceable lining made of wear-resistant material, such as rubber.

The lining of the cylindrical section of the hydrocyclone is known from the prior art, made of rubber or other wear-resistant material in the form of a cylinder ("Hydrocyclone" OA43832 (I) (Borovikov AO. and others) VO4S 5/00, VOZS 5/00, 25.08.2009, the closest analog 11.

The disadvantage of the well-known lining of the cylindrical section of the hydrocyclone is the imperfection of the geometric parameters, in particular the ratio of the height of the lining to its diameter.

This is due to the fact that the geometric relations of the lining of the cylindrical section of the hydrocyclone are defined in |1| intuitively and is not the optimal value for this hydrocyclone.

To ensure optimal technological performance and ensure reliability, the lining of the cylindrical section of the hydrocyclone must be made taking into account certain geometric ratios.

A decrease in the height of the liner of the cylindrical section of the hydrocyclone relative to the diameter leads to a deterioration of the technological indicators of the hydrocyclone, and an increase in the height leads to an increase in mass, an increase in the cost of materials, and also to a deterioration of the technological indicators.

A decrease in the thickness of the lining wall of the cylindrical section of the hydrocyclone causes a decrease in its service life and reliability, and an increase in the thickness of the lining wall of the cylindrical section of the hydrocyclone leads to an increase in the mass and a decrease in the volume of the lining of the cylindrical section of the hydrocyclone.

The task of the useful model is to improve the lining of the cylindrical section of the hydrocyclone by optimizing its geometric ratios to achieve the specified design technological indicators of the hydrocyclone.

The technical result, which is achieved by solving the given problem and using the improved lining of the cylindrical section of the hydrocyclone, is the increase in the reliability of operation and the increase in the technological indicators of the hydrocyclone.

The problem is solved by the fact that in the lining of the cylindrical section of the hydrocyclone, which is made of rubber or other wear-resistant material in the form of a cylinder, according to a useful model, the geometric parameters are selected subject to the following ratio:

Nts/Oce-(2.09-2.24)103 (1) bts-KOgce-NUIg/400 (2) where: Pce is the height of the lining of the cylindrical section of the hydrocyclone, mm;

This is the diameter of the inner surface of the lining of the cylindrical section of the hydrocyclone, mm; бцс-КОгце-ИНЗ2/400 (2) where is the wall thickness of the lining of the cylindrical section of the hydrocyclone, mm;

H - hardness of rubber or other wear-resistant material of the lining of the cylindrical section of the hydrocyclone according to Shore;

K - proportionality factor, K-(6.9-12.5)105.

Due to the optimization of the geometric parameters of the lining of the cylindrical section of the hydrocyclone, the specified design technological indicators of the hydrocyclone are ensured. This is explained by the fact that with the optimal ratio of geometric parameters, the maximum effect of separation of the material to be classified in the hydrocyclone is achieved.

In order to achieve greater convenience when installing the lining in the hydrocyclone body and increasing the density of the connection, there are triangular protrusions on the outer side of the flange.

In the future, the improved lining of the cylindrical section of the hydrocyclone is explained by an example of its implementation with reference to the attached drawings.

In Fig. 1 shows the lining of the cylindrical section of the hydrocyclone, general view.

In Fig. 2 shows the flange of the lining of the cylindrical section of the hydrocyclone with a triangular protrusion.

In Fig. C shows a hydrocyclone equipped with a lining of the cylindrical section of the hydrocyclone, general view.

The lining 1 of the cylindrical section of the claimed hydrocyclone is made (Fig. 1) of rubber or other wear-resistant material in the form of a cylinder.

The peculiarity of liner 1 is that the geometric parameters of the cylindrical section of the hydrocyclone are selected subject to the following ratio:

Нцс/Огцо-(2.09-2.24) 103, (1) бце-Когце-НЗИ2/400 (2) where: Пцес - height of the lining of the cylindrical section of the hydrocyclone, mm;

Zo Oce - diameter of the inner surface of the lining of the cylindrical section of the hydrocyclone, mm; bead - wall thickness of the lining of the cylindrical section of the hydrocyclone, mm;

H - hardness of rubber or other wear-resistant material of the lining of the cylindrical section of the hydrocyclone according to Shore;

K - proportionality factor, K-(6.9-12.5)105.

Due to the optimization of the geometric ratios of the lining (1), (2), the best possible achievement of the specified design technological indicators of the hydrocyclone, its reliability and durability is ensured.

A decrease in the geometric ratios of the lining 1 compared to the optimal (1), (2) causes a deterioration of technological indicators, a decrease in service life and reliability, and an increase in the geometric ratios of the lining 1 compared to the optimal (1), (2) leads to an increase in its mass and also deteriorates the technological indicators of the hydrocyclone, increases the consumption of lining material.

To achieve greater convenience when installing the lining 1 and increasing the density of the connection, there are triangular protrusions 2 on the outer side of the flange (Fig. d).

Lining 1 (Fig. 1, 2) is designed to protect the inner surface of the cylindrical section of the hydrocyclone housing (Fig. 3) from abrasive wear.

The hydrocyclone (Fig. 3) includes an interconnected body 4, consisting of an upper, usually cylindrical, inlet section 5 with a tangential feed pipe b, which is also called an inlet head, a cover C, a cylindrical section 7 and several, for example two, which taper downwards, the upper and lower conical sections 8, 9, as well as the drain nozzle 10, installed along the axis of the cover Z, the sand nozzle 11 attached to the lower conical section 9 of the body 4, and the splash extinguisher 12 attached to the sand nozzle 11 of the hydrocyclone, designed to prevent splashing.

The hydrocyclone also includes the lining 16 of the cover C, the lining 13 of the inlet section 5 of the body 4, made with a tangential supply pipe 14 and the channel 15, the lining 1 of the cylindrical section 7 of the body 4, the lining 17 of the upper conical section 8 of the body 4, the lining 18 of the lower conical section 9 of the body 4, the lining 19 of the drain nozzle 10, the lining 20 of the sand nozzle 11 and the lining 21 of the fire extinguisher 12 splash.

The liner 1 of the cylindrical section 7 in the hydrocyclone works as follows.

The pulp enters under pressure into the channel 15 (Fig. C) of the tangential feeding nozzle 14 of the lining 13 of the inlet section 5 of the body 4 of the hydrocyclone.

When the pulp flows through the channel 15 of the tangential feed pipe 14 of the lining 13 of the inlet section 5 of the body 4 of the hydrocyclone, the rectilinear movement of the pulp is transformed into a curvilinear and swirling one directly under the lining 16 of the cover 3.

During further movement, the pulp carries out a vortex movement along a spiral inside sections 5, 7, 8, 9 of the body 4 of the hydrocyclone.

Under the action of centrifugal forces, solid particles of a larger (heavy) fraction, which are in a suspended state in the pulp continuously moving along a spiral inside the housing 4 of the hydrocyclone, which narrows downwards, are thrown to the periphery (to the walls of the linings 13, 1, 17, 18), due to friction forces lose speed, fall down and are removed from the hydrocyclone through the sand nozzle 11 and sprinkler 12, which prevents splashing.

And small solid particles of the fine (light) fraction, suspended in a liquid medium - clarified pulp along the axis of the hydrocyclone, where a zone of reduced pressure is formed, are removed from the hydrocyclone by an upward flow through the drain nozzle 10, located in its cover 3.

In connection with the fact that the geometric parameters of the liner 1 of the cylindrical section 7 of the hydrocyclone are selected under the condition that the ratio (1), (2) is fulfilled, the thickness of the lining 1 is optimized, the best possible combination of its material capacity and strength is ensured while ensuring the necessary internal volume of the cylindrical section 7 of housing 4 of the hydrocyclone to ensure the given design technological indicators of the hydrocyclone.

Due to this, the optimal service life is achieved and the reliability of the operation of the mentioned liner and the hydrocyclone as a whole is increased.

The given information indicates the possibility of industrial applicability of the useful model, which can be widely used in mining, metallurgy, chemical, pulp and paper, construction and other industries for size separation of materials suspended in a liquid medium - pulp, in hydrocyclones.

List of designations 1. lining of the cylindrical section of the hydrocyclone 2. triangular protrusion on the outer side of the flange of the lining of the cylindrical section of the hydrocyclone

From 3. hydrocyclone cover 4. hydrocyclone body 5. inlet section of the hydrocyclone body b. tangential feed pipe of the inlet section of the hydrocyclone housing 7. cylindrical section of the hydrocyclone housing 8. upper conical section of the hydrocyclone housing 9. lower conical section of the hydrocyclone housing 10. drain pipe 11. sand nozzle 12. splash extinguisher 13. liner of the hydrocyclone inlet section 14. tangential feed pipe liners of the inlet section of the hydrocyclone 15. channel of the tangential supply pipe of the liner of the inlet section of the hydrocyclone 16. liner of the lid of the inlet section of the hydrocyclone 17. liner of the upper conical section of the hydrocyclone 18. liner of the lower conical section of the hydrocyclone 19. liner of the drain nozzle 20. liner of the sand nozzle 21. liner of the splash extinguisher .

Claims (2)

USEFUL MODEL FORMULA 1. The lining of the cylindrical section of the hydrocyclone, made of rubber or other wear-resistant material in the form of a cylinder, which is distinguished by the fact that the geometric parameters of the lining of the cylindrical section of the hydrocyclone are selected subject to the following ratio: Ncs/Oce-(2.09-2.24 )109, (1) bcys-KOgce-NZg/400,; (2) where: Pce is the height of the lining of the cylindrical section of the hydrocyclone, mm; This is the diameter of the inner surface of the lining of the cylindrical section of the hydrocyclone, mm; bu - wall thickness of the lining of the cylindrical section of the hydrocyclone, mm; H - hardness of rubber or other wear-resistant material of the lining of the cylindrical section of the hydrocyclone according to Shore; K- coefficient of proportionality, k-(6.9-12.5)1 05, 2. The lining of the cylindrical section of the hydrocyclone, which is made of rubber or other wear-resistant material in the form of a cylinder according to claim 1, which is characterized by the fact that the flanges of the lining have triangular protrusions located on the outer side of the flange. X s zh nin pn s. And what En y y, HUK her EYashCHU I t IZ : I I : LK : o | - : t | i : n | yah : her : p : u m : 0 ЗШ Her | Oh my God! I | B: I | her DV: | GO : ko Y zh yi o KO yi Kaya yi GO KU yi her 0 Kk ! 1 Fig. 1 va a s, OK, ko o KhMK H o tyu i neon - a VO Konya Kk nah ee pokoy i ee Fig. 2