UA51270C2 - Process and device for magnetic treatment and clarification of aqueous solutions - Google Patents

Abstract

A process of magnetic treatment and clarification of aqueous solutions consists in sequential passage of aqueous solutions through the magnetic fields with different value of magnetic induction. In this case, in initial stage, when the flow of aqueous solution is subjected to the action of magnetic field with smaller value of magnetic induction, optimum conditions of polarization for aggregation, coagulation of insoluble particles are ensured, and in the final stage, when the flow of aqueous solution is subjected to the action of magnetic field with greater value of magnetic induction, optimum conditions for preventing from the association of anti-ions are ensured. A device for magnetic treatment and clarification of aqueous solutions includes a housing with a cover, consisting of the chamber of precipitation and sludge collector divided by a lattice, a partition, inlet and outlet ducts located in the upper part of the housing, the branch pipe for discharge of slime. Magnetic systems are made in the form of magnetic bars with different value of magnetic induction. The increase of efficiency of the particles removal from the aqueous solutions and optimum conditions for averting the association of anti-ions are provided.

Description

Description of the invention

The invention is intended for the purification of aqueous solutions from particles of varying degrees of dispersion and the correction of 2 physical and chemical properties of aqueous solutions to prevent sludge formation using magnetic influence and can be used in water heating, cooling and other water supply systems.

Known methods for accelerating the processes of coagulation and precipitation of impurities in devices with a unipolar magnetic system and in the range of magnetic intensity 280 - 1120E (0.028 - 0.112T) (1). 70 A known method of magnetic influence, which ensures the removal of impurities by the formation of a solid phase in the volume of water when water passes through a unipolar system of magnets with an intensity of Н - 0.8 - 10.0A/m (0.0010 - 0.0126T), which implemented in the device (21.

A known method of magnetic influence to prevent the precipitation of carbonate and other sediments in devices with a magnetic system with alternating polarity and a magnetic induction value of 0.06 - 0.10T (Z, 4). 12 The disadvantage of the known methods is low efficiency due to the lack of a complex magnetic effect on the components (of varying degrees of dispersion) of aqueous solutions to intensify their extraction and prevent the formation of carbonate and other deposits.

The closest to the proposed method, in terms of technical essence and the result that is achieved, is the method of cleaning liquids from suspended and colloidal particles by inertial-gravitational sedimentation with the use of magnetic influence on impurities that are precipitated, which is used in the device I5 | and selected as a prototype.

The disadvantage of the known method is that its implementation cannot ensure a sufficiently high efficiency of magnetic influence on dispersion transformations (aggregation, coagulation, association in aqueous solutions).

The invention is based on the task of a method of magnetic treatment and clarification of aqueous solutions and a device c 29 for its implementation by sequentially passing the latter through magnetic fields, the magnetic induction of which (He) increases in the direction of the flow of the aqueous solution, to provide optimal conditions for the polarization of particles to increase their efficiency dispersion transformations and degree of extraction and optimal conditions to prevent association of counterions.

The set task is achieved in the method of magnetic treatment and clarification of aqueous solutions, which consists in the sequential passage of aqueous solutions through magnetic fields with different magnitudes of magnetic induction, in which - at the initial stage, when the flow of aqueous solution is exposed to a magnetic field with a smaller magnitude of magnetic induction, optimal polarization conditions for aggregation and coagulation of insoluble particles are achieved, especially at the final stage, when the flow of the aqueous solution is exposed to a magnetic field with a greater magnitude "-- magnetic induction - preventing the association of counterions. 325 The task can be achieved in the method of magnetic treatment and clarification of aqueous solutions, thanks to the fact that the flow of the aqueous solution is initially exposed to a magnetic field with an induction within 0.1 -

О.2T, at the final stage - with induction in the range of 0.3 - О.8T, and the time of magnetic influence of the field at the initial stage within 0.6 - 1.2s, at the final stage - within 0.3 - 0.5s . "

The task is implemented in a device for magnetic processing and clarification of aqueous solutions, which includes a housing with a lid, which consists of a sedimentation chamber and a sludge collector, separated by a grid, with partitions, inlet and outlet nozzles located in the upper part of the housing, a sludge discharge nozzle,

From" a mesh filter element, magnetic systems made with different values of magnetic induction, while the value of the magnetic induction of the systems increases in the direction of the flow of the aqueous solution.

The task can be achieved in a device for magnetic treatment and clarification of aqueous solutions, in which the magnetic systems are made in the form of magnetic rods. i-th The set task can be achieved in a device for magnetic treatment and clarification of aqueous solutions, in which all the rods of the magnetic systems are installed with the possibility of removing them outside the case without removing the cover and depressurizing the case. o The set task can be achieved in a device for magnetic treatment and clarification of aqueous solutions, in which granular loading, for example, polystyrene foam, is placed in the volume of the mesh filter element.

As a result of the implementation of the proposed solution, in which aqueous solutions are sequentially passed through c magnetic fields, the magnetic induction of which increases in the direction of the flow of the aqueous solution, a complex effect is exerted on all components of the dispersed system. It is known |6) that the influence of an external magnetic field causes a shift (deformation) of electron clouds, which determines polarization phenomena in the solution - changes in short-range and 52 long-range interactions between the components of the solution (dipole-dipole, ion-counterion, etc.), which appear in changes

GF) of chemical, physico-chemical properties. Due to the lack of theoretical foundations, the mechanism of the influence of the magnetic field is explained on the basis of the generalization of experimental data. It is known (6) that as a result of the influence of a magnetic field, the surface tension changes, which is mainly determined by dipole-dipole interactions. In this regard, it is natural to expect a change in wetting ability. An adsorption layer of solvent molecules and dissolved components can form on the wetted surface. Thus, as a result of the influence of the magnetic field, the main stability factors of colloidal particles (adsorption-hydration, electrostatic) change. At the same time, the ability to coagulate particles can increase or decrease. It is known

Y/Y that, as a result of the influence of the magnetic field, the degree of hydration of ions changes (decreases), which contributes to the formation of associates, i.e., favorable conditions are created for the separation of dissolved components into the solid phase. The formation of associated ions can be explained from the point of view of polarization effects (dipole-ion interaction,

ion-counterion), and kinetic. As a result of the influence of the external magnetic field, the trajectory of ion movement (counterion drift) changes, which determines the possibility of increasing the local concentration of counterions and their separation into the solid phase. It is known that the effect of the influence of the magnetic field can be stabilization of the solution and prevention

Separation of soluble components into the solid phase, which is explained by a decrease in the probable convergence of counterions and the formation of associates. The polarization and kinetic phenomena discussed above occur simultaneously, are interconnected and manifest as a single complex effect of the influence of the magnetic field, which depends on certain parameters: the type of magnetic system, processing time, hydrodynamic and other conditions. Taking into account the degree of influence of the parameters in the proposed solution, the principle is realized that the complex effect of the influence of /o magnetic field, which manifests itself both in the stabilization and in the destabilization of individual components of the dispersed system, depends on the magnitude of the induction (tension) of the magnetic field and its time effect on the aqueous solution.

Fig. 1 shows graphs of the dependence of the change in the optical density of an aqueous solution after the action of magnetic fields with different magnitudes of magnetic induction on the time of magnetic action: curve 71 - for a magnetic field with a magnitude of magnetic induction equal to 0.2T; curve 2 - for a magnetic field with a value of magnetic induction equal to 0.bT. 7/5 Relative changes in optical density correspond to the processes: phase formation - dissolution - phase formation. At the same time, achieving the required effect in a system with a higher induction corresponds to a shorter exposure time and vice versa.

At the initial stage, optimal polarization conditions are provided for aggregation, coagulation of insoluble particles, which allows to increase the degree and speed of their extraction in the deposition chamber under the influence of inertial and gravitational forces. At the same time, the destabilization processes are due to an increase in the surface tension of water on the 2o surface of the phase separation, and an increase in the adsorption processes of dissolved components. Thus, colloidal particles and part of the dissolved components pass into the sediment at the same time.

Treatment of the flow of the aqueous solution with a magnetic field at the initial stage takes place under the conditions that the value of the magnetic induction is О0.2T, and the duration of the exposure is 0.bs, in contrast to the final stage, when the magnetic field with the value of the magnetic induction О.bT, the corresponding effect is achieved for the duration of the exposure field 0.1s. This method allows to ensure the process of phase formation in the metastable region for the coarsening of particles, and, therefore, the increase in the speed of their deposition. (8)

The use of a magnetic field with a higher magnetic induction at the final stage allows to provide conditions to prevent the formation of ionic associates, which can later be centers of crystallization of the solid phase. At the same time, charged particles move more chaotically and unpredictably, which reduces

See the possibility of their rapprochement and subsequent interactions. The possibility of ensuring the value of magnetic induction within 0.b6T allows to reduce the time of exposure to the magnetic field to 0.4s, while the corresponding effect using a magnetic system with a smaller value of magnetic induction is provided for a longer time, i.e. 1.4s. with

Placement at the initial stage of the movement of the flow of the aqueous solution of the magnetic system with a smaller value of magnetic induction allows to ensure optimal conditions for the extraction of colloidal particles and partially dissolved - z5 particles due to the formation of aggregates in the form of coagulated magnetic and non-magnetic particles and, thus, to prevent rapid contamination of the surface of the magnetic system with a larger magnetic induction, creating optimal conditions for the subsequent stabilization of the solution - preventing the formation of associates-counterions.

The distance of the magnetic system with the value of magnetic induction in the range of 0.1 - 0.2T from the magnetic system with the value of magnetic induction in the range of 0.3 - 0.8T makes it possible to distinguish the processes of destabilization and stabilization of the pain system of the aqueous solution according to each stage of the flow through magnetic systems. from c The implementation of magnetic systems in the form of rods reduces the resistance to the flow of an aqueous solution and its turbulence

And for the effective removal of impurities, and also contributes to the convenience of maintenance, which is due to the possibility of removal of rod magnetic systems outside the case without removing the cover and depressurizing the case in the regeneration mode.

Placement in the volume of the mesh filter element of the granular loading allows to increase the effect of extraction of both insoluble (а - 0.1 - 1Ωm) and soluble components (for example, He 72, Ge") by their adsorption on the surface of the loading grains. - The use of polystyrene foam as a granular load allows you to more accurately adjust the fractional composition of the load in order to ensure the necessary cleaning effect, as well as the filtering speed, to prevent grains from being carried out through the mesh. 7 Fig. 2 shows the general view and section of the device for magnetic treatment and clarification of aqueous solutions . o The device for magnetic processing and clarification of aqueous solutions includes a housing 1 with a cover 2, which consists of a sedimentation chamber C and a sludge collector 4, separated by a grid 5, partitions 6, inlet 7 and outlet 8 nozzles located in the upper part of the housing 1, nozzle sludge removal 9, magnetic rods 10, mesh filter element 11, granular loading 12 .

The device for magnetic treatment and clarification of aqueous solutions works as follows. o The flow of the medium to be cleaned, for example, the feed water of heating systems, enters the sedimentation chamber. At the initial stage, when the flow of the aqueous solution is exposed to a magnetic field with a value of magnetic induction in the range of 0.1 - 0.2T for 0.6 - 1.2s, particles with stronger magnetic properties are deposited on the magnetic rods and their thickening is ensured. At the same time, larger aggregates are formed in the form of coagulated magnetic and non-magnetic particles, the rate of which sedimentation increases by 3095. Thus, the majority of pollutants from aqueous solutions are removed by gravity-inertial sedimentation into the sludge collector, passing through the labyrinths of partitions (Table 1):

The effect of removing pollution particles from aqueous solutions, 90 b5

Table 1

Sludge picker - mesh filter -

The surface of the magnets is a moving element

At another 70, what is it in sh

What is it that V

KE 5-8 Proposed 5 oo

ROB 0000 Prototype Sho 5 |5 5 o what w technical solution 9 to t | In ov as vv

Hek) in all se a s is o o chn - i | GI oS PI o VYNY PESNY etc

A stream of aqueous solution containing particles with lower magnetic susceptibility and small non-magnetic particles enters the remote final stage. The effect of a magnetic field with a value of magnetic induction in the range of 0.3 - 0.8T is 0.3 - О.5Bs, which ensures the deposition of particles with weaker magnetic properties on magnetic systems and stabilization of the salt system.

Lighter magnetic and non-magnetic particles are retained by the mesh filter element. The effect of their (o) extraction in the presence of granular loading, for example polystyrene foam, increases by 2-4 times. Thus, a clarified aqueous solution enters the outlet pipe from the deposition chamber.

The reduction of sludge precipitation in the volume of the aqueous solution and on the surface of the heat exchanger, 96, as a result of the influence of a 30 magnetic field is given in Table 2.

Table? with

M Effect of action, 70 - : о зе Temperature, С - : : ю p/p In the volume of the solution On the heat exchange surface 001801. ш-в . and the mouse is lush

Thus, the proposed technical solution used in water heating systems allows to reduce the precipitation of carbonates, phosphates, sulfates from water with the formation of sediment, both in the form of sludge and - dense scale on the surface of the heat exchanger.

Information used: 1. Magnetic treatment of industrial waters "UKR NDINTI". 1988, Mo12, p.21. -I 20 2. US patent Mo4289621, cl. 210/222 (B801035/06). 3. Application 4107512, Germany, IPC 5 СО2Е1/48. c 4. A new device for magnetic water treatment. Russia - 1990 - 93, p1 - C28 - England. 5. Patent of Russia Mo2175954, cl. СО2Е1/48/ /СО2Е103:02. 6. Dushkin S.S., Yevstratov V.N. Magnetic water treatment at chemical enterprises. M., "Chemistry", 1986, p. 136. 7. Soldatov V.S. Simple ion exchange equilibria. Minsk, "Nauka", 1972, p. 224.

F) ka

Claims (8)

The formula of the invention 60 1. The method of magnetic processing and clarification of aqueous solutions, which consists in the sequential passage of aqueous solutions through magnetic fields with different magnitudes of magnetic induction, which differs in that at the initial stage, when the flow of an aqueous solution is exposed to a magnetic field with a smaller magnitude of magnetic induction induction, provide optimal polarization conditions for aggregation, coagulation of insoluble particles, and at the final stage, when the flow of an aqueous solution is exposed to a magnetic field with a greater magnitude of magnetic induction, because they provide optimal conditions for preventing the association of counterions. 2. The method of magnetic treatment and illumination of aqueous solutions according to claim 1, which differs in that the flow of the aqueous solution is initially exposed to a magnetic field with a magnetic induction value of 0.1-0.2 T, and at the final stage is exposed to a magnetic fields with a magnitude of magnetic induction in the range of 0.3-0.8 T. C. The method of magnetic treatment and clarification of aqueous solutions according to claims 1, 2, which differs in that the time of magnetic exposure of the field at the initial stage is within 0.6-1.2 s, and the time of magnetic exposure of the field at the final stage is within 0 ,3-0.5 s. 4. The device for magnetic processing and clarification of aqueous solutions includes a case with a cover, which consists of a sedimentation chamber and a sludge collector, separated by a grid, partitions, inlet and outlet nozzles located in the upper part of the case, a nozzle for removing sludge, magnetic systems, mesh 70 filtering an element that differs in that the magnetic systems are made with different values of magnetic induction, while the value of the magnetic induction of the system increases in the direction of the flow of the aqueous solution. 5. Device for magnetic treatment and clarification of aqueous solutions according to claim 4, which is characterized by the fact that the magnetic systems are made in the form of magnetic rods. 6. A device for magnetic processing and clarification of aqueous solutions according to claim 5, which is characterized by the fact that all /5 magnetic systems are installed with the possibility of removing them outside the case without removing the cover and depressurizing the case. 7. The device for magnetic treatment and clarification of aqueous solutions according to claims 4, 5, 6, which is characterized by the fact that a granular loading is placed in the volume of the mesh filter element. 8. The device for magnetic processing and clarification of aqueous solutions according to claim 7, which differs in that polystyrene foam is used as a granular charge. c schi 6) "c) in c "- I c) - and? 1 - ime) -i (42) ime) 60 b5