RU2255797C1 - Device for hydrodynamic treatment of liquid - Google Patents

Abstract

FIELD: cavitation treatment of liquids and their mixtures and dispersion of solid particles in them; chemical, petrochemical and other industries.

SUBSTANCE: proposed device has housing with rotary disk mounted inside it. Disk has conical member mounted coaxially relative to it. Generatrix of member may straight or curvilinear line. Mounted above disk at adjustable clearance is chamber.

EFFECT: enhanced efficiency.

7 cl, 2 dwg

Description

The invention relates to the technology of cavitation treatment of a liquid or mixture of liquids and solid particles dispersed in them. It can be used in chemical, petrochemical and other industries.

BACKGROUND OF THE INVENTION AND BACKGROUND

A device is known for hydrodynamic processing of a liquid, comprising a vessel for liquid and an acoustic vibrator installed in the vessel (see RU 2209112, IPC B 01 J 19/10, publ. 04.06.2004).

A significant disadvantage of this device is the dependence of the energy transfer of acoustic vibrations into the medium on the viscosity of the medium. In addition, the device has a low efficiency.

A device for cavitation treatment of liquid, made in the form of a confuser-diffuser system (RU 95120655, IPC B 01 F 5/00, publ. 02.27.1998).

When the processed fluid passes through the confuser-diffuser system, the fluid velocity in the diffuser increases, which leads to a drop in pressure below the saturated vapor pressure and to the occurrence of cavitation. This device is more effective than an acoustic vibrator. However, this device also does not have a controlled effect both on the formation of cavitation bubbles and on their collapse. In addition, the area of cavitation exposure is located in the wall zone of the diffuser, which reduces the efficiency of cavitation treatment of the liquid. In many cases, it is necessary to introduce solid particles into the fluid to be treated, which is unacceptable for the confuser-diffuser system.

A device for cavitation treatment of liquid, made in the form of a rotor and a stator with slots for liquid, is known as a rotary pulsation apparatus (see RF patent No. 2178337, IPC ⁷ B 01 J 19/00, 01/20/2002). The formation of cavitation bubbles in these devices is achieved due to the protrusions moving at the periphery with a high speed. However, in this case, cavitation cavities and bubbles are formed on the surface of the working tool, which dramatically reduces the effectiveness of cavitation treatment.

A device is known for hydrodynamic processing of a liquid, comprising two or more nozzle openings arranged to feed oncoming jets of liquid (see application for US patent No. 2003/0199595, NKI 516/20, publ. 23.10 2003).

In the known device, a more efficient treatment of the liquid takes place, since the vortex formed during the collision of the jets first acts on the liquid, and when the velocity at the periphery of the vortex core reaches a critical value, cavitation bubbles appear. The second effect is that cavitation bubbles formed in the zone of the vortex core move to the center of the vortex core and collapse.

However, in this known device, the feed of the liquid to be treated occurs along a certain surface, as a rule, this is the inner surface of the pipe or nozzle, that is, a boundary layer of liquid is always formed on this surface, and this in turn leads to a loss of liquid energy on the walls. This phenomenon is very significant for viscous fluids. For example, to increase the speed of a liquid stream, it is necessary to reduce the diameter of the nozzle, however, this boundary layer is prevented from decreasing along the walls of the nozzle.

This disadvantage is eliminated in the known fluid hydrodynamic processing device, where a centrifugal force, which is applied directly to the boundary layer on the surface of the rotating disk, can be applied to the liquid boundary layer, and this device is closest to the present invention.

The aforementioned fluid hydrodynamic processing device comprises a housing, a disk mounted in the housing, a drive configured to transmit torque to the disk (see US Patent No. 6132080, NKI 366/286, publ. 10/17/2000).

In this known device, liquid is supplied to the surface of a rotating disk. In this case, the boundary layer of liquid interacts with the smooth surface of each of the rotating disks and, under the action of centrifugal force, moves to the periphery of the disk. When moving the fluid boundary layer, fluid turbulization occurs on the surface of the disk, i.e., the formation of vortices. Thus, hydrodynamic treatment of the liquid is possible. However, the vortices formed in this case quickly leave the surface of the disk, acquiring an insignificant rotation energy, which does not allow a more efficient hydrodynamic treatment of the liquid.

Thus, the problem solved by the present invention is to increase the efficiency of the hydrodynamic treatment of a liquid.

The technical result that can be obtained by solving the problem is to significantly increase the energy of the vortex and the formation of a vortex with cavitation bubbles in its core.

The problem is achieved with the achievement of the above technical result is solved due to the fact that in the known device for hydrodynamic processing of liquids containing a housing, a disk mounted in the housing, a drive configured to transmit torque to the disk on the end surface of the disk, conical to it, is installed conical an element forming a straight or curved line, and a camera is installed above the surface of the disk, coaxial to it and the conical element, while between the end of the chamber and the end surface ska a gap, as well as by the fact that

- the gap between the end of the chamber and the end surface of the disk is adjustable;

- the generatrix of the conical element is made with a radius of curvature equal to 1-10 radii of its base;

- the generatrix of the conical element is made in the form of a hyperbola;

- the generatrix of the conical element is made in the form of a circle segment;

- the Reynolds number for the conical element is selected in the range of 2000 - 5500 and is determined by the ratio R _e = ΩR ² / ν, where

Ω is the angular velocity of rotation of the conical element (rad / sec);

R is the radius of the base of the conical element (meter);

ν is the kinematic viscosity of the treated fluid (m ² / s);

- the dimensionless geometric factor of the chamber is selected within 2 - 3 and is determined by the ratio - α ₁ = H / R, where H is the height of the chamber, i.e., the distance from the base of the conical element to the upper cut of the chamber;

- the camera is axisymmetric.

The invention is illustrated by figures.

Figure 1 shows a section of a device for processing liquid in a vertical plane, indicating the directions of fluid flow and the designation of the vortex formation zone.

Figure 2 presents a section of the device in the horizontal plane.

According to FIG. 1, a fluid hydrodynamic processing device comprises a housing 1, a disk 2 mounted in the housing 1, and a drive. The shaft 3 is connected to the drive and is configured to transmit torque to the disk 2. On the end surface 4 of the disk 2, a conical element 5 is mounted coaxially to the disk 2. The generatrix 6 of the conical element 5 is straight or curved. A chamber 7 is mounted coaxially to the disk 2 above its end surface 4, and a gap 9 is made between the lower end 8 of the cylindrical chamber 7 and the end surface 4 of the disk 2. The gap 9 is made with the possibility of regulation, that is, with the possibility of changing its width. At the opposite end 10 of the cylindrical chamber 7, a hole 11 is made for supplying the processed fluid. To remove the treated fluid, an outlet 12 is provided (FIG. 2).

In the present invention, the hydrodynamic treatment of a liquid, for example the preparation of emulsions, is as follows. The processed fluid enters the volume of the device through the hole 11 and fills the volume of the axisymmetric chamber 7.

When the disk 2 is rotated with a conical element 5, its lateral conical surface sets in motion the boundary layer (conditionally indicated by the sign C of FIG. 1). In this case, two forces will act on the boundary layer: centrifugal, directed along the radius of the disk 2, and the force due to the movement of the boundary layer elements along the curvilinear generatrix and which is directed along the radius of curvature (designated as R1 in Fig. 1) of this generatrix, i.e. this force creates additional pressure on the lateral surface of the conical element 5. Together, this leads to the fact that the energy transferred to the boundary layer will be greater than in the case of a flat disk. The streamline in this case is indicated by the solid line C. In the future, part of the liquid will be directed to an adjustable gap 9, and the rest of the liquid will be directed along the inner surface of the chamber 7. This movement leads to the formation of a vortex zone between the surface of the conical element 5 and the inner surface of the axisymmetric chamber 7. The streamlines of these vortices are shown in FIG. 1 (denoted by V). Since the fluid of the boundary layer continuously enters the vortex formation zone, the vortex rotation energy increases, and this leads to the formation of a cavitation cavity at the vortex core boundary, that is, the first cycle of the fluid processing occurs - the cavity is formed in the fluid due to circular motion. In this case, the destruction of large agglomerates inside the liquid occurs. Thus, this process provides the formation of emulsions, dispersions and the like. The cavitation cavity or bubble formed at the boundary of the vortex core will be drawn into the center of the vortex, which will lead to the collapse of the bubble. When the bubble collapses, pressure and temperature increase significantly. This increase in temperature and pressure causes mechanochemical reactions in the medium of the treated fluid. On the other hand, this leads to the destruction of the vortex as an organized structure and a decrease in the hydrodynamic resistance in the zone of vortex formation. As a result, through the hole 11, the flow of liquid will increase, and most of the products of the destruction of the vortex using the disk 2 will be directed to the gap 9, where under the action of centrifugal force will be directed to the outlet 12. Thus, the processing of the liquid occurs with mechanical action on the liquid with a certain frequency.

The hydrodynamic processing parameter is the Reynolds number, which for our case is in the range of 2000-5500, is determined by the ratio

Re = ΩR ² / ν,

where Re is the Reynolds number;

Ω is the angular velocity of rotation of the cone (rad / sec);

R is the radius of the base of the conical element (m);

ν is the kinematic viscosity of the liquid (m ² / s).

The next parameter is the dimensionless geometric factor of the chamber - α ₁ = H / R, where H is the height of the chamber 7, i.e. the distance from the base of the conical element 5 to the upper cut 10 of the chamber 11. This parameter should be enclosed within 2-3.

The height of the conical element 5 can be selected in the range of 1 to 2 radii of the base of this conical element 5, and the generatrix of the conical element is made with a radius of curvature equal to 1-10 radii of its base.

Thus, the present invention implements a way to obtain a vortex structure in a liquid with predetermined parameters, the formation of cavitation phenomena in this structure, providing mechanochemical processing of the liquid and the release of the processed products from the reaction zone.

Claims (8)

1. A fluid hydrodynamic processing device comprising a housing, a disk mounted in the housing, a drive configured to transmit rotational momentum to the disk, characterized in that a conical element is installed on the end surface of the disk, forming a straight or curved line, and above the surface of the disk coaxially with it and the conical element, a camera is installed, while a gap is made between the end of the camera and the end surface of the disk. 2. The device according to claim 1, characterized in that the gap between the end of the chamber and the end surface of the disk is adjustable. 3. The device according to claim 1, characterized in that the generatrix of the conical element is made with a radius of curvature equal to 1-10 radii of its base. 4. The device according to claim 1, characterized in that the generatrix of the conical element is made in the form of a hyperbola. 5. The device according to claim 1, characterized in that the generatrix of the conical element is made in the form of a segment of a circle. 6. The device according to claim 1, characterized in that the Reynolds number for the conical element is selected within 2000-5500 and is determined by the ratio Re = ΩR ² / ν, where Ω is the angular velocity of rotation of the cone (rad / s), R is the radius of the base conical element (m), ν - kinematic viscosity of the treated fluid (m ² / s). 7. The device according to claim 1, characterized in that the dimensionless geometric factor α _{1 of the} camera is selected within 2-3 and is determined by the ratio α ₁ = H / R, where H is the height of the camera. 8. The device according to claim 1, characterized in that the camera is axisymmetric.

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