RU2270717C2 - Method of treatment of liquids - Google Patents

Abstract

FIELD: construction industry; agriculture; food industry; medicine; biology; methods of activation of liquids.

SUBSTANCE: the invention is pertaining to the method of treatment of liquids by activation and may be used in various industries, in particular, in agriculture, biology, medicine, food-processing industry at preparation of different solutions, emulsions, suspensions. The method includes compression the liquids with their subsequent squeezing through at least one nozzle with a supersonic speed at the outlet on an output and deceleration of the outgoing jet of the liquid by a barrier. Compression and squeezing of the liquid is exercised by its rotation in the fast spinning hollow rotor during a liquid movement through at least one running from the center of the rotation to the periphery full-profile channel, on the outlet of which there is an installed nozzle. The technical result of the invention is an increased degree of the liquids activation at reduction of power input costs.

EFFECT: the invention ensures an increased degree of the liquids activation at reduction of power input costs.

19 cl, 10 dwg, 2 tbl

Description

The invention relates to the activation of liquids and can be used in various industries, in particular in agriculture, biology, medicine, food industry, in the preparation of various solutions, emulsions, suspensions.

A known method of treating a fluid, comprising compressing the fluid and then displacing it through a nozzle with a supersonic velocity at the outlet and braking the outgoing fluid stream against the obstruction (RU 2031847 C1, C 02 F 1/00, 1990).

The disadvantage of this method is the insufficient degree of activation of the fluid and its contamination during processing due to the penetration of microvolumes of foreign working fluids used in the compression of the treated fluid in the hydraulic cylinders, ingress of seal wear products into the processed fluid, significant losses in the energy activation process in the hydraulic system, providing compression of the liquid, low productivity due to the presence of one working nozzle.

The objective of the invention is to obtain a clean, unpolluted liquid with a greater degree of activity and reducing energy losses for its production.

This problem is achieved by the fact that in the method of processing the liquid, including compressing the liquid and then displacing it through at least one nozzle with the exit speed required for activation and braking the outgoing liquid stream against the barrier, the liquid is compressed and displaced by rotation in a rapidly rotating hollow rotor when moving through it, at least one full-profile channel going from the center of rotation to the periphery, at the output of which the specified nozzle is installed.

And also the fact that the movement of the liquid is carried out through the specified channel of the rotor, filled with a porous filler.

And also by the fact that the braking of the outgoing liquid stream is carried out on a motionless barrier.

And also the fact that the braking of the outgoing jet of fluid is carried out on a rotating barrier.

And also the fact that the fluid is carried through the specified channel, made tapering from the center of rotation to the periphery.

And also by the fact that the movement of fluid is carried out through the specified channel located in a spiral of Archimedes.

And also by the fact that the barrier is rotated in the same direction of rotation of the rotor.

And also because the barrier is rotated in the opposite direction to the rotation of the rotor.

And also by the fact that the barrier is rotated with the same angular velocity with the rotor.

And also by the fact that as a barrier they use a stream of liquid directed towards the stream of liquid leaving the nozzle.

And also by the fact that the jet of the processed liquid has a supersonic resulting speed.

As well as the fact that the liquid jet used as an obstacle has a supersonic speed.

And also by the fact that the rotor along its axis is affected by the reactive force of a jet of liquid.

And also by the fact that the rotor perpendicular to its axis is affected by the reactive force of the liquid jet.

And also by the fact that the rotor along its axis is affected by aerodynamic lifting force generated during rotation of the rotor.

And also by the fact that the rotor is perpendicular to its axis by aerodynamic force generated during rotation of the rotor and directed towards the axis of rotation.

And also by the fact that when liquid is displaced through a nozzle, air or gas is injected into the flow of the displaced liquid.

And also by the fact that the rotor is rotated in opposite angular directions, and after the rotation of the rotor in each direction, the parameters of the processed fluid are determined.

And also the fact that as one of the parameters of the liquid determine its pH.

Figure 1 shows a General diagram of the implementation of the method and device for its implementation.

Figure 2 shows a diagram of the implementation of the method with braking the liquid emerging from the nozzle against an obstacle that may be stationary, can rotate in the same direction as the rotor, can rotate in the opposite direction to the rotation of the rotor. The rotor can rotate in opposite angular directions.

Figure 3-5 shows a diagram of the method with braking the liquid exiting the nozzle against an obstacle that rotates in the same direction as the rotor, with the same angular velocity due to the fact that the barrier is attached to the rotor with various forms of execution of the channel and the location of the barrier.

Figure 6 shows a diagram of the implementation of the method with braking the liquid exiting the nozzle against an obstacle, which is used as a stream of the same or another liquid directed towards the liquid exiting the nozzle.

Figure 7 shows a diagram of the implementation of the method with the impact on the rotor along its axis by the reactive force of a liquid jet.

On Fig shows a diagram of the implementation of the method with the impact on the rotor perpendicular to its axis by the reactive force of the liquid jet.

Figure 9-10 shows a diagram of the method with the impact on the rotor along its axis of the aerodynamic lifting force generated during rotation of the rotor, due to the different execution of the rotor.

Figure 11 shows a diagram of the implementation of the method with the action on the rotating rotor of an aerodynamic force directed to the axis of rotation.

On Fig shows a diagram of a method with the injection of air (gas) into the flow of displaced liquid.

The method of processing liquid is as follows.

Величина результирующей скорости V превышает скорость звука в воздухе. Внутренний профиль канала 2 и диаметр сопла 3 подобраны таким образом, чтобы обеспечить неразрывность потока обрабатываемой жидкости. Выходящая из сопла 3 жидкость 4 тормозится о преграду 5. Скорость вращения ротора 1 подобрана таким образом, что выходящая из сопла 3 жидкость движется с большой, например со сверхзвуковой, скоростью, а направление вращения ротора 1 выбирается предварительно. В результате жидкость активируется. Воздействие на жидкость дополнительно вращения способствует повышению степени активирования жидкости. Влияние вращения на свойства воды было исследовано, в частности, в работе М.В.Курик и др. Влияние вращения на свойства воды, «Сознание - физическая реальность», 2000 г., №6, т.5.In the hollow rotor 1 rotating with high angular velocity (Fig. 3), for example, with two full-profile channels 2 tapering to the periphery, having the shape of an Archimedes spiral and nozzles 3 installed at the outlet, the processed fluid 4 is supplied, which, when passing through the channels 2 of the rotor 1 acquires rotation, is compressed by centrifugal forces and is forced out through nozzles of small diameter 3, which are installed at the outlet of the channels 2 of the rotor 1. The resulting velocity of the jet of fluid to be treated from the nozzle 3 is vectorized and two components: V _r - radial component due to compression of liquid under the influence of centrifugal forces and V _τ - circumferential, tangential component directed tangentially to the path of rotation of jet forming nozzle

The value of the resulting velocity V exceeds the speed of sound in air. The internal profile of the channel 2 and the diameter of the nozzle 3 are selected in such a way as to ensure the continuity of the flow of the treated fluid. The liquid 4 exiting from the nozzle 3 is inhibited by the barrier 5. The rotor 1 rotational speed is selected so that the liquid exiting the nozzle 3 moves at a high, for example, supersonic speed, and the direction of rotation of the rotor 1 is preselected. As a result, the liquid is activated. Exposure of the fluid to additional rotation increases the degree of fluid activation. The effect of rotation on the properties of water was investigated, in particular, in the work of MV Kurik et al. The effect of rotation on the properties of water, “Consciousness is a physical reality”, 2000, No. 6, v.5.

To impart a laminar motion to the flow of the processed fluid (without breaking the flow continuity), the full-profile channel 2 of the rotor 1 is filled with a porous filler. This contributes to the drip outflow of the liquid 4 from the nozzle 3, which enhances the effect on the liquid and leads to its greater activation.

The obstacle 5, about which the activated fluid is braked, can be fixed, rotating in one direction or the other with the rotor 1 (direction), and at the same or different speed with the rotor 1. At the same speed of the obstacle and the rotor, the obstacle can be set to the rotor itself. The magnitude and direction of the angular velocity of rotation and its radius are determined previously by determining their influence on the desired degree of activation of the liquid.

As an obstacle 5, for example, a supersonic jet of liquid 6 can be used, directed towards the stream of liquid 4 exiting the nozzle 3. For this, for example, a similar rotor 7 with channels 8 ending in nozzles 9 similar to nozzles 3 is installed coaxially with the rotor 1 A liquid stream exits the nozzles 9, directed towards the liquid stream exiting the nozzles 3. When the liquid jets collide, they are activated.

The rotor 1 along its axis is affected by the reactive force of the jet of liquid 4 and the force generated as a result of the impact on the lower surface 10 of the rotating rotor 1 of the jet of liquid 6. This helps to unload the bearings of the rotor. As a barrier 5 can use the mutually directional surfaces of the rotors 10 and 11.

The rotor 1 along and perpendicular to its axis is affected by aerodynamic forces arising from the rotation of the rotor. To do this, on the rotor 1 on its surface perform aerodynamic wings 12, 13, which create aerodynamic forces R ₁ and R ₂ . The axial force R ₁ acts on the rotor along its axis and unloads the bearings of the rotor 1. The tangential force R _{2 is} directed to the axis of rotation of the rotor and partially unloads its structure from the action of centrifugal forces. Creating a lifting aerodynamic force R _{1 is} possible due to the design of the rotor itself, which has aerodynamic quality. For example, the upper surface of the rotor is made convex 17, and the bottom is flat 18.

When liquid is displaced through a nozzle, air or gas 19 is injected into the displaced liquid stream. The presence of air in the fluid flow contributes to an increase in the force acting on the fluid as a result of the occurring pulsed influences on it as a result of the cavitation.

The effectiveness of activating effects on the processed fluid is shown in table 1, from which it follows that the above exposure factors provide a significant increase in consumer properties of liquids.

The main difference between this method and the known one is shown in Table 2, from which it follows that there are no microcontaminants in the treated liquid.

Preliminarily, before the start of the liquid treatment, the treatment regimes are studied. For this, the rotor is rotated for some time in opposite angular directions, and after the rotor rotates in each direction for a certain time (usually before steady state), the parameters of the treated liquid are determined at a certain speed. As a liquid parameter, for example, the pH of the liquid is determined.

Table 1
Comparative evaluation of the known inkjet and the proposed rotor-jet method for activating liquids (water and its derivatives) Type of processing Working pressure of liquid compression, MPa Bactericidal treatment.
The initial microbial number of water 95-100 Comparative evaluation of the anti-inflammatory effect of orthophene,% of control Effect on the development of wheat,% of control Effect on mitotic cell division green mass the roots Chromosomal aberrations, M ± Mitotic index in shares, M ± Prototype Inkjet 100 in the high pressure cylinder 5-7 42.8 107.1 90,4 0.255 ± 0.027 0.349 ± 0.008 The proposed rotary jet 100 at a rotor speed of ω = 18700 rad / s and radius R = 0.25 m 2-3 58 120,4 102.8 0.198 ± 0.052 0.315 ± 0.016 Comparative Test Results and Conclusions Increase in antibacterial activity of rotor-jet treated (RSO) water The growth of anti-inflammatory action (reduction of edema of the foot in laboratory rats) when using RSO An increase in the mass of the aerial parts and roots of plants after 20 days Jet and RSO water does not have a pronounced mutagenic or antimutagenic effect

table 2
Comparative assessment of the purity of the processed fluid according to the known and proposed rotary jet processing method Working pressure of water, MPa fifty one hundred 150 200 250 The known method (RF Patent No. 2031847) - - + + + The proposed method of RNO - - - - - Note: + visually detectable oil film and micro sludge
- changes in the quality of treated water are not recorded

Claims (19)

1. A method of activating a fluid, comprising compressing the fluid and then displacing it through at least one nozzle with supersonic velocity at the outlet and braking the outgoing jet of fluid against the barrier, characterized in that the compression and displacement of the supplied fluid is carried out by rotating it in a rapidly rotating hollow rotor when moving through it, at least one coming from the center of rotation to the periphery of the full-profile channel, the output of which is installed the specified nozzle. 2. The method according to claim 1, characterized in that the fluid is carried through the specified channel of the rotor filled with a porous filler. 3. The method according to claim 1, characterized in that the braking of the outgoing stream of liquid is carried out on a fixed barrier. 4. The method according to claim 1, characterized in that the braking of the outgoing stream of liquid is carried out on a rotating barrier. 5. The method according to claim 1, characterized in that the fluid movement is carried out through the specified channel, made tapering from the center of rotation to the periphery. 6. The method according to claim 1, characterized in that the fluid is carried through the specified channel located in a spiral of Archimedes. 7. The method according to claim 4, characterized in that the barrier is rotated in the same direction of rotation of the rotor. 8. The method according to claim 4, characterized in that the barrier is rotated in the opposite direction to the rotation of the rotor. 9. The method according to claim 4, characterized in that the barrier is rotated with the same angular velocity with the rotor. 10. The method according to claim 1, characterized in that as a barrier use a stream of liquid directed towards the stream of liquid exiting the nozzle. 11. The method according to claim 1, characterized in that the jet of the processed fluid has a supersonic resulting speed. 12. The method according to claim 10, characterized in that the stream of liquid used as a barrier has a supersonic speed. 13. The method according to claim 1, characterized in that the rotor along its axis is affected by the reactive force of a jet of liquid. 14. The method according to claim 1, characterized in that the rotor is perpendicular to its axis by the reactive force of the liquid jet. 15. The method according to claim 1, characterized in that the rotor along its axis is subjected to aerodynamic lifting force generated during rotation of the rotor. 16. The method according to claim 1, characterized in that the rotor is perpendicular to its axis by aerodynamic force generated during rotation of the rotor and directed towards the axis of rotation. 17. The method according to claim 1, characterized in that when the liquid is displaced through the nozzle, air or gas is injected into the displaced liquid stream. 18. The method according to claim 1, characterized in that the rotor is rotated in opposite angular directions, and after the rotation of the rotor in each direction, the parameters of the processed fluid are determined. 19. The method according to claim 1, characterized in that as one of the parameters of the liquid determine its pH.

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