RU2323888C1 - Method of free-flowing substance processing by energy of ultrasonic vibrations - Google Patents

Abstract

FIELD: production methods.

SUBSTANCE: method includes the feeding of free-flowing substance to the working chamber, the influence to it by energy of ultrasonic vibration link of emission several source of ultrasonic vibrations and with the following output of processed substance from working chamber. The steam of the substance during the entrance is separated into several steams and for each of them it is given the basic direction, which would be changed some time later. The ultrasonic influence is done in four zones of vibration of different types, which are intersected. Simultaneously with the changing of direction of the steam motion of separated parts in the output of every zone of the ultrasonic influence, it is changed the speed of motion, the profile of transversal section and its sizes, and at the output of processed substance from working chamber it is united in one steam.

EFFECT: it is increased the efficiency of processing and process productivity.

8 cl, 3 dwg

Description

The invention relates to ultrasound equipment and can be used in various technological processes carried out using the energy of ultrasonic (hereinafter referred to as ultrasound) vibrations. It can be used, for example, in the processing of milk, juices and wine, for the preparation of suspensions and drilling fluids, for the enrichment of minerals and the separation of water-alcohol mixtures, for the neutralization of mercury-containing solid waste, as well as for the cleaning of fuels and lubricants, and mechanical products for various purposes.

There is a method of ultrasonic treatment, according to which the medium to be treated is poured into an open vessel and for the appropriate time subjected to ultrasonic vibrations created by a source installed in the center of this vessel [1].

The main disadvantage of this method is that it does not provide the possibility of processing a liquid medium in the process of its circulation.

There is also known a method of ultrasonic treatment, in which a fluid medium is passed through a working chamber and exposed to it by the energy of ultrasonic vibrations created by sources installed in the bottom of this chamber [2].

The main disadvantage of this method is that it, due to the "bottom" location of the sources of ultrasonic vibrations, does not provide uniform effects on a fluid medium around the entire perimeter of its flow.

In addition, there is a known method of processing a fluid medium with the energy of ultrasonic vibrations, which in its technical essence and the achieved result when using it is the closest to the proposed one and adopted as a prototype. According to this method, a fluid medium is passed through a pipeline through a working chamber made in the form of a truncated cone and is exposed to it by the energy of ultrasonic vibrations created by sources symmetrically located on the larger base of this chamber, which has the shape of a ring and encloses the pipeline [3].

Such a constructive implementation of the working chamber allows for ultrasonic treatment of the medium to be processed along the entire perimeter of its flow, but does not fully ensure uniformity of ultrasonic treatment, which is the main disadvantage of this method.

This disadvantage is due to the fact that in the central part of the working chamber, the flow of the processed fluid medium predominantly has a laminar flow, a quite sufficient speed of movement and is subjected to ultrasonic vibrations reflected by the conical wall, and in the peripheral part of the working chamber, the flow has a turbulent character, the minimum speed of movement is the influence of ultrasonic vibrations as reflected by the conical wall of the chamber, and committed by its annular base.

It should also be noted that when implementing this method of ultrasound, the processing of a fluid medium is carried out using only one type of vibrations (longitudinal) and it occurs in only one zone, while the vibrations reflected by the conical wall of the chamber and the vibrations made by its annular base, damp each other somewhat.

Due to all these disadvantages, this method can be characterized as not providing the required quality of processing a fluid medium.

The technical problem to which the invention is directed is to increase the efficiency of ultrasonic processing, which, in turn, allows to increase the productivity of the process.

The problem is solved by creating several zones of ultrasonic exposure and by ensuring the uniformity of ultrasonic exposure in each of them.

The solution of the problem in the method of processing a fluid medium with ultrasonic vibrations energy, including the supply of a fluid medium to the working chamber, exposure to it with ultrasonic vibrations energy, performed in the working chamber by means of emitting links of several sources of ultrasonic vibrations, and the subsequent withdrawal of the treated medium from the working chamber are achieved due to the fact that the flow of a fluid medium when it enters the working chamber is divided into several separate streams and each of them is informed that it is oriented relative to the longitudinal axis of symmetry of the working chamber, the initial direction of movement, which is then changed, while the ultrasonic effect is carried out mainly in four zones and vibrations of at least two different types, which are given propagation directions that intersect at least in two planes, and simultaneously with a change in the direction of motion of the individual flows of the medium being processed, carried out at the outlet of each zone of ultrasonic exposure, the speed of their two zheniya, cross-sectional shape and dimensions, and at the outlet of treated medium from the working chamber of its combined into a single stream.

The solution of the task of the method also contributes to the fact that:

- when dividing a fluid medium into separate streams, they are given mainly the same shapes and sizes of the cross section, direction and speed of the initial movement;

- the initial direction of movement of each of the individual flows is reported in a plane that is perpendicular to the longitudinal axis of symmetry of the working chamber or is located at some angle to this axis;

- changing the initial direction of motion of individual flows is carried out mainly by 90 degrees;

- changing the shape and size, speed and direction of movement of individual flows in the zones of ultrasonic exposure is carried out by means of each emitting link of all sources of ultrasonic vibrations;

- ultrasonic action is carried out by creating longitudinal, longitudinal-bending, radial and radial-bending vibrations by the emitting link of each ultrasonic source;

- ultrasonic action is carried out, creating emitting links of different ultrasonic sources of oscillation with the same and / or with different in magnitude acoustic parameters;

- the separate flows of the treated medium when it leaves the working chamber are mainly given the same shape and size of the cross section, direction and speed.

This also contributes to the fact that the proposed method, in comparison with the known, has several more differences, which are that:

- to separate flows at their entrance to the working chamber different initial directions of movement are reported;

- in the process of ultrasonic exposure, the shapes of the individual flows are successively changed from flat to round and, vice versa, from round to flat, and give their cross sections different geometric dimensions;

- the value of the angle of deviation of the initial direction of motion of an individual stream, relative to a plane perpendicular to the longitudinal axis of symmetry of the working chamber, does not exceed 45 degrees.

The invention is illustrated by drawings:

figure 1 presents a longitudinal section of a device with which the proposed method can be implemented in the processing of any fluid medium;

figure 2 shows a section along aa in figure 1;

figure 3 presents the appearance of the source of ultrasonic vibrations.

In the device for processing a fluid medium with the energy of ultrasonic vibrations, ensuring the implementation of the proposed method, a sealed working chamber (see Fig. 1) by means of a supply 1 and a receiver 2 nozzles having the same shape and equal cross-sectional areas is integrated into the transport medium of the medium to be processed (on drawings not shown) and is made in the form of a body of revolution with a rectangular cross-section. It has a flow distributor consisting of a central 3 and peripheral 4 parts, and is equipped with several sources of ultrasonic vibrations symmetrically spaced around each of which is formed by a magnetostrictive transducer 5 and a multifaceted radiating link 6, which is made of metal and acts as a transformer of the direction of propagation of ultrasound vibration emitted by the transducer 5.

The housing of the working chamber, consisting of a rectilinear cover 7, a round outer wall 8 and a rectilinear bottom 9, is tightly connected to the supply 1 and receiving 2 pipes by means of union nuts (not indicated by numbers in the drawings).

The medium flow distributor is made integral and has its central 3 and peripheral 4 parts, respectively, separates the supply 1 and receiving 2 pipes from one another and divides the working chamber cavity into two communicating cavities “A” and “B”, the last of which has round outer and inner sections. The Central part 3 of the flow distributor is made in the form of a hollow cylinder 10, which has an internal partition 11 and through circular holes 12 and 13, symmetrically arranged in two groups around the circumference on different sides of the partition 11. The peripheral part 4 of the flow distributor is made in the form of a flat ring, which is installed on the outer surface of the cylinder 10 in the same plane with the partition 11 and has symmetrically arranged in two concentric circles, through holes of a trapezoid 14 and a round 15 shape. The through holes 12, 13 and 15 have the same dimensions and the same total area in their groups. While the holes 12 and 13 are made in such a way that their axis of symmetry parallel to the peripheral part 4 of the flow distributor.

The magnetostrictive transducer 5 of the ultrasonic vibrations source, designed for a frequency of 19.5 kilohertz and assembled from plates made of K-65 alloy, is made of two rods, equipped with an excitation winding 16 and a shielding plate 17, placed in a water-cooled housing 18 and connected to the ultrasonic generator (on drawings not shown). In the device, all the transducers 5 are made with the same geometric dimensions and, therefore, have the same acoustic parameters.

The multifaceted radiating element 6 of the source of ultrasonic vibrations in the simplest and most optimal embodiment for calculating geometric dimensions is (see Fig. 3) a regular rectangular parallelepiped, which is made with a central through hole 19 and has two large 20, two medium 21 and two small 22 facets. In the working version of the device (see Fig. 2), the correct shape of the rectangular parallelepiped should be slightly modified and the emitting link 6 should be performed with a longitudinal cross section in the form of a regular trapezoid, i.e. with monotonously decreasing width. This allows you to use a larger number of radiating links and, therefore, to increase the total area of the radiating surfaces.

Radiating links, which are connected rigidly and directly (i.e. without an intermediate link) to magnetostrictive transducers 5 by one of their middle faces, are installed in the working chamber so that the surfaces of their free middle 21 faces are located in the middle of the height of the through holes 14 of the peripheral part 4 flow distributors, which have the shape and dimensions corresponding to this face, and are located on a concentric circle closest to the longitudinal axis of the working chamber. Moreover, the narrowest of the smaller faces of each radiating link faces the longitudinal axis of the working chamber, and its two large faces 20 are parallel to the large faces of two adjacent radiating links, which are located at a certain distance from it. Moreover, all radiating links 6 by means of rubber gaskets 23 are acoustically isolated from the peripheral part 4 of the flow distributor (gaskets insulating radiating links 6 from the bottom 9 of the working chamber are not indicated by positions in the drawings) and using jumpers 24 and 25 made of polyurethane and located staggered in two concentric circles, separated from one another. In the device, all the radiating links 6 have the same shapes and sizes and are set so that the distances from their outer surfaces to the walls of the working chamber and to the central part 3 of the distributor have the same value.

The following is an example of a specific implementation of the proposed method, not excluding other options for its implementation in the scope of the claims.

Before starting operation of the device, the cavity of the housing 18 is connected to a water circulation system cooling the transducers 5 and includes an ultrasonic generator. Under the influence of the magnetic field created by the windings 16, each of the transducers 5 is excited and begins to perform longitudinal vibrations, which are transmitted to the radiating link 6. In each radiating link, due to its geometric shape and corresponding dimensions, the longitudinal vibrations of the converter are transformed. As a result of this, the free edges 21 (middle) and 22 (smaller) of the radiating link 6 and the wall of its hole 19 make intense vibrations. These oscillations can be characterized, respectively, as longitudinal (longitudinal-bending) and radial (radial-bending), i.e. as vibrations of two different species that have a propagation direction mutually intersecting in two planes oriented one relative to the other at an angle of 90 degrees. In this case, the amplitude of oscillations of the radiating link in the changed directions is greater than the initial amplitude of the oscillations of the converter, and its large faces 20 practically do not oscillate.

The processed fluid medium, for example milk, is supplied to the working chamber through the pipe branch pipe 1 by a common stream, which enters the left compartment of the central part 3 of the flow distributor. This compartment has a closed volume and is formed by a solid partition 11 and the inner wall of the hollow cylinder 10, which is made with round, symmetrically located holes 12.

Entering these holes and passing through them, the processed liquid medium is divided into several separate streams that have the same round shape with the same dimensions of their cross section and acquire the same initial direction of motion in a plane perpendicular to the longitudinal axis of symmetry of the working chamber. This is because the diameters of the holes 12 are equal to each other, and their axis of symmetry lie in one plane common to them, which is parallel to the cover 7, the peripheral part 4 of the flow distributor and the middle faces 21 of the radiating links 6.

At the exit from the openings 12, individual flows of the processed liquid medium, filling the cavity “A”, merge with each other, acquire a flat shape, change the speed of movement, go through the first zone of ultrasonic action (middle face 21 of the radiating link) and, entering the direction of the initial movement, enter round holes 15 of the peripheral part 4 of the flow distributor.

Entering into these openings and passing through them, the processed liquid medium is again divided into several separate streams, which acquire the same round shape with the same cross-sectional sizes and together change 90 degrees of direction of their movement. At the exit from the openings 15, individual streams of the processed liquid medium, filling the outer part of the cavity “B”, merge with each other, again acquire a flat shape, once again change the speed of movement and fall under the influence of the second zone of ultrasonic impact (one of the smaller faces 22 of the radiating link) .

From the external part of cavity “B”, the processed liquid medium, again with a flat shape of its flows, but with a smaller cross section, through the spaces between the radiating links 6, not blocked by jumpers 25, enters the circular holes 19 (third zone of ultrasonic exposure) emitting links 6. Then it passes through these holes and through the spaces between the radiating links, not blocked by jumpers 24 (the next change in shape, speed and direction of movement), enters the inner part of the cavity "B" and falls under the action of the fourth zone of ultrasonic impact (the second of the smaller faces 22 of the radiating element), which leaves through round holes 13, the number of which and the arrangement are identical to holes 12. After passing through holes 13, the individual flows of the processed fluid flow, acquiring the same round shape with the same transverse dimensions sections, enter the right compartment of the Central part 3 of the flow distributor. In this compartment, which has a closed volume and is formed by a solid partition 11 and the inner wall of the hollow cylinder 10, the individual streams of the processed fluid medium are combined into a single unit and leave the device through the pipe 2 in a common flow.

It should be noted that in the event that for some reason a single ultrasonic treatment is unsatisfactory, then the fluid medium can be sent for additional processing, and its supply to the working chamber can also be carried out through pipe 2.

At the end of processing the entire volume of a fluid medium and reaching its predetermined parameters, the cavity of the housing 18 is disconnected from the water circulation system cooling the transducers 5, and the ultrasound generator is turned off.

From the point of view of acoustic parameters, it should be noted that the ultrasonic effect in the implementation of the proposed method can be carried out with constant or with changing acoustic characteristics, in the frequency range up to 80 kilohertz, with an oscillation amplitude not exceeding 60 microns and with an intensity close to 35 W / cm ² In this case, the radiating links of different ultrasonic sources can create oscillations with the same and / or different amplitude amplitude, the magnitudes of the amplitudes and intensity of oscillations can be established pour with an inversely proportional relationship, and the processing time is directly proportional to the viscosity of the medium being treated.

A comparative analysis of the known and proposed methods of ultrasonic treatment of a circulating fluid medium in terms of process performance shows significant advantages of the latter. These advantages are achieved due to the fact that ultrasonic treatment is carried out in more than one zone, the flow of the medium being treated in the treatment zone is constant and smaller in cross section, and vibrations having different types of components and intersecting propagation directions are introduced directly from radiating link and without using the reflective capabilities of the constituent elements of the working chamber.

Information sources

1. USSR Copyright Certificate, No. 277.427, B06B 1/06, 1970.

2. Patent of the Russian Federation, No. 2.067.079, C02F 1/36, 1996.

3. USSR patent, No. 261.280, C22B 9/02, 1970.

Claims (8)

1. A method of processing a fluid medium with ultrasonic vibration energy, including supplying a fluid medium to the working chamber, exposing it to ultrasonic vibration energy performed in the working chamber by means of emitting links of several sources of ultrasonic vibrations, and subsequent withdrawal of the treated medium from the working chamber, characterized in that the flow of a fluid medium when it enters the working chamber is divided into several separate streams and each of them is informed oriented relatively longitudinal axis of symmetry of the working chamber, the initial direction of movement, which then change, while the ultrasonic effect is carried out mainly in four zones and vibrations of at least two different types, which give the propagation directions, mutually intersecting in at least two planes, and simultaneously with a change in the direction of motion of the individual flows of the medium being processed, carried out at the outlet of each zone of ultrasonic exposure, their speed of movement, the shape of the transverse sections and its dimensions, and when the treated medium exits the working chamber, it is combined into a single stream. 2. The method according to claim 1, characterized in that when dividing a fluid medium into separate streams, they are given mainly the same shape and size of the cross section, direction and speed of the initial movement. 3. The method according to claim 1, characterized in that the initial direction of movement of each of the individual flows is reported in a plane that is perpendicular to the longitudinal axis of symmetry of the working chamber or is located at some angle to this axis. 4. The method according to claim 1, characterized in that the change in the initial direction of motion of the individual flows is carried out mainly by 90 °. 5. The method according to claim 1, characterized in that the change in the shape and size, speed and direction of movement of individual flows in the zones of ultrasonic exposure is carried out by means of each emitting link of all sources of ultrasonic vibrations. 6. The method according to claim 1, characterized in that the ultrasonic action is carried out by creating longitudinal, longitudinally-bending, radial and radial-bending vibrations by the emitting link of each ultrasonic source. 7. The method according to claim 1, characterized in that the ultrasonic action is carried out, creating emitting links of different ultrasonic sources of oscillation with the same and / or with different in magnitude acoustic parameters. 8. The method according to claim 1, characterized in that the individual flows of the treated medium when it leaves the working chamber are predominantly given the same shapes and sizes of the cross section, direction and speed of movement.

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