UA68610U - Lining of hydrocyclone apex - Google Patents

Abstract

A lining of hydrocyclone apex is made of a durable material, preferably an elastomer, in the form of a hollow body (2) of rotation, with upper (3) and lower (4) ends (3,4) and an axial tapered bore (5) tapering from larger inlet diameter(D) located at the upper end (3) toward the smaller outlet diameter (d) located from the lower end (4) of lining (1), and the body of rotation (2) further comprises an axial outlet cylindrical hole (6) connected from the bottom to the tapered bore (5) along the radius (R) of connection, at the same time the diameter (d) of the cylindrical bore (6) is equal to the outlet diameter (d) of the tapered bore (5), and the height (d) of cylindrical bore (6) makes 0.1-0.3 of the height (h) of tapered bore (5), and the radius (R) of connection makes 0.1-0.9 of the diameter (d) of cylindrical bore (6).

Description

The useful model belongs to the constructions of channels for the heavy fraction of the tops of the conical part of hydrocyclones with wear-resistant elements and can be used in mining, metallurgy, chemical, construction and other branches of technology, for example, for dry or wet separation of materials into fractions using cyclones or hydrocyclones.

From the state of the art, the lining of the sand nozzle of the hydrocyclone, made of a wear-resistant material, mainly of elastomer, in the form of a hollow body of rotation, with upper and lower ends and an axial conical hole, made of such that it narrows from the larger inlet diameter, located on the upper end, towards the smaller outlet diameter, located on the side of the lower end of the liner. 00; WHO3B5/34; 01/25/2010, the closest analogue is the prototype (11.

In the well-known lining of the sand nozzle of the hydrocyclone (1), the outlet diameter (а), inlet diameter (СУ) and the height (п) of the axial conical opening are made under the condition of ensuring the following ratios: а: 0-0.43-0.56; (1) a: n-0.33-0.44. (2)

It should be noted that the specified ratios are valid only for the constructions of linings of sand nozzles of hydrocyclones, which have an axial conical opening with a taper angle c; - 7-16".

This is explained by the following calculations. At 0-1; a: 0-0.43; a: n-0.33 a-0.43; a: -0.43: 0.33-1.3; Y90y-0.5(I-0.43):1, 3-0.215; c-Ags id 0215-12". At 0-1; a: 0-:0.43; a: n-0.44 a-0.43; a: n-0.43: 0.44-0.977; shcha-0.5(1-0.43):0.977-0.291; azAgs food 0.291-16"7. At 0-1; a: p-0.56; a: n-0.33 a-0.56; n-0.56: 0.33-1.697; What-0.5(1-0.56)71.697-0.130; sh-Ags 1d 0.173577.

At 0-1; a: 0-0.56; a: n-0.44 a-0.56; и-0.56: 0.44-1.27; eidos-0.5(1-0.56)711, 27-0.215; o-Ags 19 0.173-97.

Hydrocyclones with such taper angles (p-7-167) have a limited field of application.

Whereas, depending on the purpose of the hydrocyclone, the angle o; conicity is a wider range of values o-5-85"7.

The reliability of the well-known lining of the sand nozzle of the hydrocyclone is determined by the rate of wear of the lower edge of the drainage axial conical hole.

During the operation of the well-known lining of the sand nozzle of the hydrocyclone I1| the lower edge of the drainage axial conical opening of the liner is subjected to intense abrasive wear by the flowing stream of sand, in the form of a mainly torch that rotates and diverges at the exit.

At the same time, as a result of abrasive wear, the output diameter of the drainage axial conical opening of the liner increases significantly, as a result of which the normal mode of operation of the hydrocyclone to separate the pulp into fractions is violated, and upon reaching critical wear, the liner quickly fails and requires replacement, which reduces the service life and reduces operational reliability of the well-known lining of the hydrocyclone sand nozzle.

The problem that the useful model is aimed at solving is the improvement of the shape and the selection of the optimal ratio of the geometric parameters of the drain channel (hole) of the lining, so that the sand flows out in a stream mainly in the form of a rotating cylindrical torch at the exit, and the lower edge of the axial drain hole does not would be subject to intense abrasive action of the flowing sand flow and premature critical wear of the lining of the sand nozzle of the hydrocyclone.

The technical result, which is achieved by solving the task and using the improved lining of the sand nozzle of the hydrocyclone, consists in increasing the service life and increasing operational reliability.

The task is solved, and the technical result is achieved by the fact that in the lining of the sand nozzle of the hydrocyclone, made of a wear-resistant material, mainly of elastomer, in the form of a hollow body of rotation, with upper and lower ends and an axial conical hole, made in such a way that it narrows from the larger input diameter (0), located on the upper end, towards the smaller output diameter (41), located on the side of the lower end of the lining, according to a useful model, the body of rotation additionally has an axial outlet cylindrical hole, connected from below with a conical hole along the radius (K) connection, while the diameter (dg2) of the cylindrical hole is equal to the initial diameter (y) of the conical hole, the height (Нг) of the cylindrical hole is 0.1-0.3 of the height (Pi) of the conical hole, and the radius (K) of the connection is 0.1 -0.9 diameter (dg2) of the cylindrical hole.

Due to the fact that the body of rotation additionally has an axial output cylindrical hole, because it is connected from below with a conical hole along the radius (K) of the connection, a change in the sand discharge torch is achieved, which will smoothly turn from a conical rotating flow of sand into a cylindrical one in the area of the conical hole a rotating stream of sands in the area of the cylindrical hole, and at its exit, an output cylindrical torch of rotating sands is formed.

Thanks to this, the lower edge of the cylindrical hole is subjected to significantly less abrasive wear, which significantly increases the service life and increases the operational reliability of the improved lining of the sand nozzle of the hydrocyclone.

It has been established experimentally that the best performance indicators of the lining of the sand nozzle of the hydrocyclone are achieved when the following optimal ratios of its geometric parameters are ensured, i.e. when the diameter (dg2) of the cylindrical hole is equal to the initial diameter (y:) of the conical hole, the height (2) of the cylindrical hole is 0 ,1-0.3 of the height (Pi) of the conical hole, and the radius (K) of the connection is 0.1-0.9 of the diameter (d") of the cylindrical hole.

The selection in the liner of the ratio of the height (yg2) of the cylindrical hole and the height (Pi) of the conical hole is less than the lower limit of P2: pi « 0.1 is inappropriate, because in this case the outflowing sand flow does not have time to transform from the rotating conical sand flow, in the area of the conical opening, into the rotating cylindrical flow of sands, in the area of the cylindrical opening, and at its exit, an output torch is formed that rotates and diverges, of the removed sands, as a result of which the lower edge of the drainage axial cylindrical opening of the liner is subjected to intensive abrasive wear by the flow of flowing sands.

The choice in the lining of the ratio of the height (yg2) of the cylindrical hole to the height (Pi) of the conical hole greater than the upper limit of P2: No » 0.3 is also not advisable, because in this case the mode of formation of the rotating sand flow in the zone of the conical hole is significantly disturbed. since the height of the latter becomes smaller at a constant calculated height (H) of the lining, which reduces the quality of pulp separation in the hydrocyclone into fractions.

The selection of the radius (K) of the connection in the liner is less than the lower limit of the diameter (dg2) of the cylindrical hole K«0.1d2 is not advisable, because in this case a smooth transition from a conical hole to a cylindrical hole is not formed, which prevents the smooth transformation of the sand outflow torch from the conical flow of sand , rotating, in the zone of the conical opening, into a cylindrical flow of sand, rotating, in the zone of the cylindrical opening.

З The selection of the radius (K) of the coupling in the lining is greater than the upper limit of the diameter (аг) of the cylindrical hole K»0.9d2 is also impractical, because in this case the length of the cylindrical surface of the cylindrical hole decreases, and the transformation of the torch of sand outflow from the rotating conical flow of sand, in the zone of the conical hole into the cylindrical flow of sand, which rotates, in the zone of the cylindrical hole, does not occur at all.

Therefore, in this case, at the outlet of the cylindrical opening of the lining of the sand nozzle of the hydrocyclone, a rotating and diverging output torch of the removed sand is formed, as a result of which the lower edge of the drainage axial cylindrical opening of the lining is subjected to intensive abrasive wear by the flow of flowing sand.

In addition, the improved lining of the sand nozzle of the hydrocyclone can be used in hydrocyclones, the conicity angle of which, in comparison with the known (1|, is a wider range of values of co; - 5-85".

In the future, the improved lining of the sand nozzle of the hydrocyclone is explained with drawings and an example of its implementation with references to the attached drawings.

In fig. 1 shows the lining of the hydrocyclone sand nozzle, general view, longitudinal section.

In fig. 2 shows a fragment of the lining of the sand nozzle of the hydrocyclone.

In fig. C shows the lining after its installation in the sand nozzle of the hydrocyclone, longitudinal section.

The lining (1) of the sand nozzle of the hydrocyclone (Fig. 1, 2) is made (Fig. 1) of a wear-resistant material, mainly of elastomer, in the form of a hollow body of 2 rotations, with upper and lower 4 ends (3, 4) and an axial conical hole 5, made in such a way that it narrows from the larger inlet diameter 0, located on the upper end 3, towards the smaller outlet diameter a, located on the side of the lower end 4 of the liner 1.

A feature of the improved liner 1 is that the body 2 of rotation additionally has an axial output cylindrical hole b, connected from below with a conical hole 5 along the radius K of the connection, while the diameter d2 of the cylindrical hole 6 is equal to the output diameter a: of the conical hole 5 (Fig. 2) , the height of the cylindrical hole 6 is 0.1-0.3 of the height of the conical hole 5, and the radius

K coupling is 0.1-0.9 of the diameter d2 of the cylindrical hole 6.

Lining 1 is made with an outer edge 7 and a total height H equal to the sum of the height Pi 60 of the conical hole 5 and the height 2 of the cylindrical hole 6, i.e. H - Pi -- H".

In industrial use, the lining 1 (Fig. C) is installed in the hollow cylindrical body 8 of the sand nozzle 9.

The cylindrical body 8 of the sand nozzle U is made with a flange 10 on the upper end, intended for connection to the flange 11 of the body 12 of the hydrocyclone 13.

The lining 1 is installed inside the cylindrical body 8 of the nozzle 9 so that its outer edge 7 is located between the flange 11 of the body 12 of the hydrocyclone 13 and the flange 10 of the body 8 of the sand nozzle 9, after which the mentioned flanges 11, 10 are fastened with bolted connections 14 and clamped between them the outer edge 7 of the lining 1.

After installation, the lining 1 occupies the position shown in fig. 3.

The lining 1 of the sand nozzle 9 of the hydrocyclone 13 works as follows.

The vortex flow of the pulp of separated materials from the conical part of the hydrocyclone 13 flows along a helical spiral into the axial channel consisting of the connected conical 5 and cylindrical 6 holes (5, 6) of the lining 1 of the sand nozzle 9.

Under the action of centrifugal forces along the axis of the conical 5 and cylindrical holes (5, 6) of the lining 1 of the sand nozzle U, a zone of reduced pressure is created, and a zone of increased pressure is created along their periphery.

As a result, intensive dispersion (separation) of pulp materials into fractions occurs.

At the same time, the light fraction rises upward into the hydrocyclone 13 and is discharged from it into the drain, and the heavy fraction (sand) is thrown to the liner 1 of the body 8 of the sand nozzle 9 under the action of centrifugal forces.

Practically, the heavy fraction descends in a helical spiral inside the body 12 of the hydrocyclone 13 to the inlet diameter Y of the liner 1 and enters the zone of the conical opening 5 in the form of a rotating conical stream of sand, and passing through the zone of radius K of the connection, the conical stream of sand smoothly turns into a cylindrical one a rotating stream of sands in the area of the cylindrical hole b, and at its exit, an output cylindrical torch of rotating sands is formed.

Thanks to this, the lower edge of the cylindrical hole would be subject to much less abrasive wear and erosion, which significantly increases the service life and increases the operational

From the reliability of the improved lining 1 sand nozzle 9 hydrocyclone 13.

The best performance indicators of the lining 1 of the sand nozzle 9 of the hydrocyclone 13 are achieved when the following optimal ratios of its geometric parameters are ensured, i.e. when the diameter of the cylindrical hole 6 is equal to the initial diameter of the conical hole 5, the height p2 of the cylindrical hole b is 0.1-0, 3 of the height y: of the conical hole 5, and the radius K of the connection is 0.1-0.9 of the diameter d2 of the cylindrical hole 6.

The improved lining 1 of the sand nozzle 9 of the hydrocyclone 13 can be used in hydrocyclones whose conicity angle c makes up a wide range of c values; - 5-85".

Having reached a critical level of wear, the lining 1 of the sand nozzle 9 of the hydrocyclone 13 is replaced with a new one.

The given information confirms the possibility of industrial applicability of the improved lining of the hydrocyclone sand nozzle, which can be widely used for dry or wet separation of materials into light and heavy fractions using cyclones or hydrocyclones in mining, metallurgy, chemical, construction and other engineering industries.

List of designations 1 - lining 2 - body of rotation

C - upper end 4 - lower end 5 - axial conical hole b. - axial output cylindrical hole 7 - outer rim 8 - sand nozzle housing 9 - sand nozzle 10 - sand nozzle flange 11 - hydrocyclone housing flange 12 - hydrocyclone housing 13 - hydrocyclone 14 - bolt connection

H - design height of lining bo r - input diameter of axial conical hole d: - output diameter of axial conical hole

No - the height of the axial conical hole d2 - the diameter of the axial output cylindrical hole 2 - the height of the axial output cylindrical hole

BA - the radius of connection of the axial conical hole with the axial cylindrical hole of the liner

Claims (1)

USEFUL MODEL FORMULA The lining of the sand nozzle of the hydrocyclone, which is made of a wear-resistant material, mainly of elastomer, in the form of a hollow body (2) of rotation, with upper (3) and lower (4) ends (3,4) and an axial conical hole (5) , made in such a way that it narrows from the larger inlet diameter (0), located on the upper end (3), towards the smaller outlet diameter (a), located on the side of the lower end (4) of the liner (1), which differs in that the body (2) rotation additionally has an axial output cylindrical hole (6) connected from below with a conical hole (5) along the radius (K) of the connection, while the diameter (аг) of the cylindrical hole (6) is equal to the output diameter (y:) of the conical hole ( 5), the height (P2) of the cylindrical hole (6) is 0.1-0.3 of the height (Pi) of the conical hole (5), and the radius (K) of the connection is 0.1-0.9 of the diameter (аг) of the cylindrical hole (6). and this zhrkkkkkkku rode: svv for oS zva vo shnek! And lk | sh I | men Shk ; 1 ! Z - i and shen SHY: That day I roti and VO 4: and i; оо ге ши ше С шыни 3 Н ши ше Сн я) B я те мк: IZ o NNYA KNEU teki OM EN ; Sobetne peeekeyuennnnnakh fr and Ho until their ho «r «rig. p: still ze NO inn inn with JAK sn; Mei PM ve NI a an ii i | - их ня ОМ ж ее еВ СЗШ их Бен В Н ше: ж Ше: з хе В Ше ; b In the same days and, yirog. WITH