RU47772U1 - DIRECT HYDROCYCLONE - Google Patents

Abstract

The invention relates to devices for separating suspensions under the influence of centrifugal forces using vortex flows combined with filters, and can be used in the energy, chemical and petrochemical industries. The direct-flow hydrocyclone contains a cylindrical body, an axial cowling located at the inlet of the body and equipped with a means for swirling the flow, a central pipe coaxial with the body, and a slot between the central pipe and the body communicates with an additional chamber with a pipe for removing the condensed fraction. A cone-shaped filtering baffle with a taper of 1: 4 to 1:10 is located coaxially with the housing and the central pipe, is connected by a base to the central pipe, and is tapering into the housing by the tapering part. The slot covers the part of the filtering partition closest to the base. The flow of suspension enters the cylindrical body and is twisted in a spiral. The heavy fraction passes through the gap and enters an additional chamber. The clarified fraction passes through a filter baffle, washed by a vortex stream, which carries particles of impurities through a gap into an additional chamber. The clarified fraction passing through the filtering partition through the central pipe is discharged from the hydrocyclone.

Description

Technical field

The invention relates to devices for the continuous separation of suspensions, and more particularly, to devices for separation of suspensions under the influence of centrifugal forces using vortex flows combined with filters, and can be used, for example, in the energy, chemical and petrochemical industries.

State of the art

Known hydrocyclone [1], which contains a housing with a tangential inlet, a drain pipe for outputting a light product and a discharge fitting for outputting a heavy product. The drain pipe of the hydrocyclone is equipped with a filter element. The disadvantages of the described design of the hydrocyclone include tangential fluid injection and the need to change the axial direction of the vortex flow to the opposite, which leads to an increase in the dimensions of the structure and increased hydraulic resistance, causing a loss of flow head. The filter element is clogged with particles of contaminants, and to clean it, you must turn off the device from operating mode.

Known horizontal hydrocyclone [2], including a cylindrical body with a tangential nozzle for supplying the initial suspension, drain and sand nozzles, a chamber with a filter element installed in it and fortified after the drain nozzle

a perforated grate placed between the filter element and the drain pipe. The disadvantages of the described design of the hydrocyclone also include tangential fluid injection and the need to change the axial direction of the vortex flow to the opposite, which leads to an increase in the dimensions of the structure and increased hydraulic resistance, causing a loss of pressure head. The filter element is under constant shock and vibration, which leads to its accelerated wear.

Known gas-liquid separator [3], which includes a cylindrical body with a central conical fairing at the inlet, equipped with swirling flow blades, and a truncated conical insert at the outlet, as well as branch pipes of the clarified and condensed fractions. The disadvantage of this device is the low efficiency of the separation of the suspension, due to the lack of a filter element.

Closest to the claimed technical solution adopted for the prototype is a horizontal hydrocyclone [4], which includes a cylindrical body with a central cowl at the inlet and a truncated conical insert at the outlet, branch pipes for bleaching and thickened fractions, and a central pipe. It is equipped with a cylinder-conical chamber placed coaxially inside the housing with an axial cowl mounted in it with flow swirling blades, and an additional chamber with a perforated partition installed inside it. In this case, the central pipe is fixed at one end in a perforated partition, and the other is buried in a cylinder-conical chamber. The disadvantages of this device include structural complexity, repeated

branching and merging, as well as a change in cross section, acceleration and deceleration of fluid flows, which leads to increased hydraulic resistance, causing a loss of flow head. The filtering partition is under constant shock and vibration, which leads to its accelerated wear.

Disclosure of invention

The purpose of the claimed utility model is to simplify the design and increase the durability of the hydrocyclone. The technical result, which is achieved by the claimed design, is to simplify and cheapen the design of the hydrocyclone, reduce hydraulic resistance and increase the durability of the filtering partition due to its cleaning by the fluid flow with the exception of shock and vibration.

The technical result is achieved in that the direct-flow hydrocyclone contains a cylindrical body, an axial cowling located at the inlet of the body and provided with means for swirling the flow, a central pipe located coaxially with the body with the formation of a gap between the central pipe and the body, communicating with an additional chamber provided with a pipe for removal of the condensed fraction, and a filter baffle, which has the shape of a cone with a taper from 1: 4 to 1:10, the filter baffle is located coaxially with the body and the center noy base pipe and is connected to the central tube, and the tapered portion is immersed in the body, wherein the gap between the central tube and the housing cover nearest to the base portion of the filter septum.

Direct-flow hydrocyclone works as follows. The flow of the suspension enters the cylindrical body, flows around the axial cowl located at the inlet of the body, equipped with means for swirling the flow, as a result of which it is twisted in a spiral. In a vortex flow, a heavy fraction containing coarse impurity particles thickens in the peripheral region, and a light clarified fraction is collected in the central part of the flow. The thickened fraction passes through the gap between the housing and the central pipe and enters an additional chamber equipped with a pipe for removing the thickened fraction. The clarified fraction passes through the filtering partition, which traps the smallest particles of impurities. At the same time, the filtering partition is constantly washed by a vortex flow, which blows away the particles of impurities that accumulate on it and through the slit discharges the particles of impurities into an additional chamber, from where they are removed together with the condensed fraction. The clarified fraction passing through the filtering partition through the central pipe is discharged from the hydrocyclone.

In a particular case of the implementation of the claimed utility model, the means for swirling the flow is made in the form of a helical surface having from two to four turns in increments of 0.3d to 1.5d, where d is the inner diameter of the housing.

In a particular case of the implementation of the claimed utility model, the width of the gap between the central pipe and the housing is from 0.1d to 0.25d, where d is the inner diameter of the housing.

In a particular case of the implementation of the claimed utility model, the axial fairing is connected to the central pipe by one or more rods.

In a separate case of the implementation of the claimed utility model, the filtering partition is placed on the frame of the rods connecting the axial fairing with the central pipe.

In a separate case of the implementation of the claimed utility model, the central pipe with an axial fairing, means for swirling the flow, connecting rods and a filter partition located on the frame of the rods are made with the possibility of extraction from the housing and the additional chamber.

Compared with the prototype, the filter baffle has a cone shape with a taper from 1: 4 to 1:10, the filter baffle is located coaxially with the body and the central pipe and is connected by a base to the central pipe, and is tapering into the housing, with a gap between the central pipe and the housing covers the part of the filtering partition closest to the base that is new. The implementation of the filtering septum in the form of a cone with a taper from 1: 4 to 1:10, the location of the filtering seam coaxially with the housing and the central pipe, attaching the filtering septum with the base to the central pipe, immersing its tapering part into the housing, the gap between the central pipe and the housing covering the part of the filtering partition closest to the base allows simplifying and cheapening the design of the hydrocyclone, reducing the hydraulic resistance and increasing the durability of the filtering partition due to its cleanliness fluid flow. Thus, a new set of essential features is achieved technical result.

Brief Description of the Drawings

The figure shows a diagram illustrating the possibility of implementing the inventive utility model. The following notation is used in the diagram:

1 - cylindrical body;

2 - axial fairing;

3 - means for swirling the flow;

4 - the central pipe;

5 - additional camera;

6 - pipe for removal of the condensed fraction;

7 - connecting rods;

8 - filtering partition.

Utility Model Implementation

The possibility of implementing the inventive utility model is illustrated by the diagram shown in the figure.

Direct-flow hydrocyclone contains a cylindrical body 1, an axial fairing 2 located at the inlet of the body and provided with means for swirling the flow 3. Means for swirling the flow 3 is made in the form of a helical surface having from two to four turns in increments from 0.3d to 1.5d where d is the inner diameter of the housing 1. A central pipe 4 is located coaxially with the housing 1, so that there is an annular gap between the central pipe and the housing. The width of this gap is from 0.1d to 0.25d, where d is the inner diameter of the housing 1. The gap communicates with an additional chamber 5, equipped with a pipe 6 for removal of the condensed fraction. The axial fairing 2, equipped with a means for twisting the flow 3, is connected to the Central pipe 4 by one or more rods

7, serving as frames for the filtering partition 8. The filtering partition 8 has the shape of a cone with a taper from 1: 4 to 1:10. It is located coaxially with the housing 1 and the central pipe 4 and is connected by a base to the central pipe 4, and tapering part is immersed in the housing 1. The gap between the central pipe and the housing covers the part of the filtering closest to the base. The Central pipe 4 with an axial fairing 2, connecting their rods 7 and located on the frame of the rods of the filter partition 8 are made with the possibility of extraction from the housing 1 and the additional chamber 5.

Direct-flow hydrocyclone works as follows. The flow of the suspension enters the cylindrical housing 1, flows around the axial fairing 2 located at the inlet of the housing and passes through the means 3 for swirling the flow. Since this tool is made in the form of a helical surface having from two to four turns in increments of 0.3d to 1.5d, where d is the inner diameter of the housing 1, the cross section of the spiral channel is from (0.3d) × (0, 5d-0.5δ) to (1.5d) × (0.5d-0.5δ), where δ is the diameter of the axial fairing. As a result, the cross section of the spiral channel, at least, does not exceed the cross section of the cylindrical body, which is 0.785d ² . Therefore, twisting in a spiral, the flow is additionally accelerated. If the pitch of the spiral surface is less than 0.3d, then the flow encounters excessive hydraulic resistance; if the pitch of the spiral surface is greater than 1.5d, then the flow does not receive the necessary acceleration. In an accelerated vortex flow, a heavy fraction containing coarse impurity particles thickens in the peripheral region, and a light clarified fraction is collected in the central part of the flow. The condensed fraction passes through the gap between the housing

1 and the central tube 4. The width of this gap is from 0.1d to 0.25d, so that the cross section of the gap is from 0.1πd ² to 0.25πd ² and, at least, does not exceed the cross section of the cylindrical body. As a result, only a part of the stream containing the heaviest and largest particles of contaminants passes through the gap. This fraction enters the additional chamber 5, equipped with a pipe 6 for removal of the condensed fraction. The clarified fraction passes through the filtering partition 8, which retains the smallest particles of impurities. If the gap width is less than 0.1d, then the condensed fraction encounters excessive resistance and partially enters the filtering partition, clogging it strongly with impurity particles; if the slit width is greater than 0.25d, then the suspension flow freely passes through the slit without being forced to pass through the filtering partition. The filtering baffle 8 is constantly washed by a vortex flow, which carries away the particles of impurities that accumulate on it and through the slot discharges the particles of impurities into an additional chamber 5, from where they are removed together with the condensed fraction. The clarified fraction passing through the filtering partition 8 through the central pipe 4 is discharged from the hydrocyclone. If there is a need for forced cleaning of the filter baffle 8 and means for swirling the flow 3, then the central pipe 4 together with the connecting rods 7, the cowling 2, means for swirling the flow 3 and the filter baffle 8 are removed from the housing 1 and the additional chamber 5 and subjected to external mechanical cleaning .

Industrial applicability

Direct-flow hydrocyclone can be used in industry. The inventive design is simple, cheap, has low hydraulic resistance and at the same time ensures the durability of the filter partition. These qualities make the use of the claimed design possible and appropriate, for example, in the energy, chemical and petrochemical industries. The manufacture of a once-through hydrocyclone of the described construction is possible by known and widely used in industry methods using equipment traditionally used in chemical engineering.

Sources taken into account:

1. RF patent No. 2180272, IPC В 04 С 5/12, В 04 С 9/00, publ. 03/10/2002, Hydrocyclone / Sabitov S.3., Ziazetdinov A.3., Akhsanov R.R., Sabitov A.S.

2. Auth. testimonial. USSR No. 528122, IPC B 04 C 5/13, publ. 09/15/1976 Horizontal hydrocyclone / Baturov V.I., Baidukov V.A., Sokolov V.I.

3. French patent No. 2142568, IPC B 04 C 5/00, publ. 02/02/1973, a gas-liquid separator / J. Langlois.

4. Auth. testimonial. USSR No. 639170, IPC B 01 D 45/12, B 04 C 3/00, publ. 03/10/1995 Horizontal hydrocyclone / Baidukov V.A., Glagolev N.I., Baturov V.I. (prototype).

Claims (6)

1. Direct-flow hydrocyclone containing a cylindrical body, an axial fairing located at the inlet of the body and equipped with a means for swirling the flow, a Central pipe located coaxially with the body with the formation between the Central pipe and the body of the gap, communicating with an additional chamber equipped with a pipe for removal of the condensed fraction and a filter baffle, characterized in that the filter baffle has a cone shape with a taper from 1: 4 to 1:10, the filter baffle is located coaxially with the housing and central pipe and attached to the base of the Central pipe, and tapering part is immersed in the housing, and the gap between the Central pipe and the housing covers the closest to the base of the filter partition. 2. The hydrocyclone according to claim 1, characterized in that the means for swirling the flow is made in the form of a helical surface having from two to four turns in increments of 0.3d to 1.5d, where d is the inner diameter of the housing. 3. The hydrocyclone according to claim 1, characterized in that the width of the gap between the Central pipe and the housing is from 0, 1d to 0.25d, where d is the inner diameter of the housing. 4. The hydrocyclone according to claim 1, characterized in that the axial fairing is connected to the central pipe by one or more rods. 5. The hydrocyclone according to claim 4, characterized in that the filtering partition is placed on the frame of the rods connecting the axial fairing with the Central pipe. 6. The hydrocyclone according to claim 4, characterized in that the central pipe with an axial fairing, means for swirling the flow and connecting rods connecting them are made with the possibility of extraction from the housing and the additional chamber.