UA152047U - A way to randomly clean the liquid - Google Patents

Abstract

The method of arbitrary liquid purification consists in the formation of ordered flows of solvent molecules in the pores of a semipermeable lyophilic membrane, the asymmetry of the solvent in the pores of which is provided by the formation of a gradient of structural organization, and the arbitrary movement of these flows is directed according to the gradient of structural organization into the volume with a pure solvent, as well as in the intensification of arbitrary solvent flows due to the action of a heterogeneous electric field and ultrasonic waves on the value of the gradient of structural organization of the solvent in the pores of the specified semipermeable lyophilic membrane. Arbitrary liquid purification is carried out in the pores of a semipermeable symmetrical lyophilic membrane. The asymmetry in the system and the gradient of the structural organization of the solvent in the pores of the semipermeable symmetric lyophilic membrane and the formation of arbitrary fluid flows corresponding to this gradient are created by pre-exposing the electrode located on the side of the purified liquid outlet from the membrane to the liquid in the pores of the semipermeable symmetric lyophilic membrane. Further intensification of the resulting flow is carried out by increasing the power of the electric field and ultrasound action on the liquid in the pores of the membrane.

Description

A useful model concerns liquid purification using membranes, namely ways to intensify the process of arbitrary water purification.

A known method of arbitrary liquid purification (patent of Ukraine Mo 25309A, IPC VO1061/00,

VO1012/00, publ. 25.12.1998, Bull. Mob), which consists in the formation of an entroposmotic flow of a solvent to be purified through a lyophilic membrane into a volume with pure solvent due to the use of a lyophilic membrane, which is given the property of semi-permeability due to the reduction of the diameter of the pores on one side of the membrane to a size comparable to the size of the particles solute, and the membrane itself is placed in such a way that its side with a smaller pore diameter faces the volume with pure solvent.

This method does not require the use of external energy and is environmentally friendly. But the disadvantage of this method is the low productivity of the process of arbitrary liquid purification due to the use of only natural diffusion of solvent molecules.

A known method of arbitrary liquid purification, chosen for the closest analogue (patent

Mo 125409 of Ukraine, IPC 8B01012/00, B01061/00, publ. 10.05.2018, point Mo 9), which consists in the formation of ordered streams of solvent (liquid) molecules in the pores of a semipermeable lyophilic membrane, the asymmetry of which is ensured by the existence of cone-shaped pores, and the arbitrary movement of these streams is directed into the volume with pure solvent. Intensification of the diffusion of solvent molecules through the semipermeable asymmetric lyophilic membrane is additionally carried out due to the action of a non-uniform electric field on the magnitude of the gradient of the structural organization of the solvent in the pores of the semipermeable asymmetric lyophilic membrane and the action of ultrasonic waves on the magnitude of the gradient of the structural organization of the solvent in the pores of the semipermeable asymmetric lyophilic membrane.

This method provides intensive cleaning of the liquid due to the increase in the CO gradient of the liquid in the pores of the semi-permeable asymmetric lyophilic membrane through the action of a non-uniform electric field and ultrasonic waves. The disadvantage is the need to form the initial asymmetry of the semipermeable lyophilic membrane due to the creation of cone-shaped holes, which is a very difficult and expensive technological operation.

The purpose of this useful model is to simplify the process of arbitrary liquid purification and reduce the costs of its implementation.

To solve the problem, according to a useful model, arbitrary cleaning of the liquid is carried out in the pores of the semipermeable symmetrical lyophilic membrane, and the asymmetry in the system and the gradient of the structural organization of the liquid in the pores of the semipermeable symmetrical lyophilic membrane and the formation of arbitrary liquid flows corresponding to this gradient are created by the preliminary action of a non-uniform electrical the field of the electrode, located on the side of the exit of the purified liquid from the membrane, on the liquid in the pores of the semi-permeable symmetrical lyophilic membrane, and the further intensification of the resulting flow is carried out by increasing the power of the electric field and the action of ultrasound on the liquid in the pores of the membrane.

Application of the proposed intensive technology for arbitrary water purification using a semipermeable symmetrical lyophilic membrane solves the problem of providing fresh water to arid regions and will improve the ecological situation. This technology is based on the use of mainly informational influence on the liquid, rather than energy, and, unlike water desalination technologies by evaporation or reverse osmosis, is low-cost.

Theoretical rationale

All physical and chemical phenomena associated with the arbitrary movement of liquid obey the principle that is reflected in the generalizing phenomenon called entroposmosis. The following definition of entroposmosis is proposed: all liquids have the property of moving arbitrarily in the direction where the structure of the liquid (solvent) is more ordered, compacted, that is, according to the gradient of structural organization (SO) of the liquid 11.

In Ukrainian patent No. 25309, the conical pores of the semi-permeable lyophilic membrane form a CO gradient, according to which entroposmotic liquid microflows are self-organized from chaotic thermal movement, which are directed according to the CO gradient of the liquid.

In the system "mineralized water - semipermeable symmetrical lyophilic membrane - fresh water" arbitrary flows of water molecules in the volume with mineralized water are formed. Analysis of CO levels, for example, in seawater -CO: and fresh water -CO shows that CO1»CO». This is a case of classical Van't Hoff osmosis. If in the system "mineralized water - semipermeable symmetrical lyophilic membrane - fresh water" in the volume of fresh water, an electrode is placed and a non-uniform electric field is activated, then an electric field gradient and a CO gradient of water generated by it will be formed in the pores of the membrane, which will stop the flow in the volume with mineralized (for example, sea) water and forms an arbitrary flow into the volume with fresh water according to the water CO gradient. This happens according to the principle of the theory of entroposmosis: the CO gradient is stronger than the difference in CO levels.

The theory of entroposmosis reasonably leads to an important conclusion: if the driving force of the ordered flow of liquid molecules is the CO gradient, then the speed of this flow is proportional to the value of the CO gradient. Thus, to intensify the flow of liquid molecules, it is necessary to apply physical factors that increase the CO of a liquid, for example, water.

The following factors contribute to the preservation and growth of water CO: compressed conditions (lyophilic membrane pore walls), the effect of an electric field, the effect of the pressure of sound waves |1|. Instead of the complex manufacture of cone-shaped pores in a semipermeable membrane, it is expedient to form an electric field gradient in water and a corresponding water CO gradient by simply turning on an inhomogeneous electric field. The initial formation of the water CO gradient in the pores of the semipermeable symmetric lyophilic membrane due to the action of the stationary inhomogeneous electric field emitted by the electrode naturally causes the formation of microflows from the volume of water to be purified into the volume with purified water. Next, to increase the value of the water CO gradient and intensify the microflows of water in the pores of the semipermeable membrane, the action of the ultrasound generator is included, and the power of the electric field is also regulated.

The ability of sound waves to exert pressure on material objects through air was discovered by V.Ya. Alberg in 1903 (2). Konovalov discovered the ultrasonic effect in liquids |Z), in which ultrasonic waves caused an increase in the movement of water in the direction indicated by the CO gradient of water.

The arbitrary movement of water through the pores of the membrane occurs without friction as a manifestation of the phenomenon of superfluidity, the result of the will of water.

To explain the essence of the proposed technology of arbitrary water purification in fig. 1 shows a cross-section of the general view of the device for arbitrary water purification with the preliminary application of the action of a non-uniform electric field to form a water CO gradient in the pores of the membrane and subsequent intensification of the process of arbitrary movement of water molecules through a semi-permeable symmetrical lyophilic membrane by the action of ultrasound and regulation of the power of the electric field; in fig. 2 - the scheme of the formation of microflows of water molecules in a volume in which the water has a higher level of CO (mineralized water) according to the theory of osmosis according to Van't Hoff; in fig. 3 - general view of a semipermeable symmetrical lyophilic membrane under the action of a non-uniform electric field.

The device for arbitrary water purification includes containers for the volume of water 1 to be purified and for purified water 2, between which a semi-permeable lyophilic symmetrical membrane 3 is installed, in the pores of which water CO gradients 4 arise after the electrode 6 is activated , which emits a non-uniform electric field, which is installed in the volume for purified water 2. In the volume for water 1 to be purified, an ultrasound generator 7 is installed. The volume of water 1 to be purified passes through a semi-permeable lyophilic membrane With in the form of microflows of water molecules 8. Purified water 2 through the nozzle 9 can be directed to the place of its accumulation.

The method of arbitrary water purification is used as follows.

To implement the proposed method, a device is used, which is a container divided by a semipermeable symmetrical lyophilic membrane 3 into a volume filled with water 1 to be desalinated (for example, sea water) and a volume with purified water 2. Semipermeable symmetrical lyophilic membrane C is a canvas made of composite polyamide material. The size of the pores of the membrane is 0.0001 μm, which ensures the selectivity of the membrane at the level of 99.0 95. The metal electrode 6, which emits a stationary inhomogeneous electric field with a voltage of 0.5 kV, is placed at a distance sufficient to affect arbitrary microflows of water 8. On the other side of the semi-permeable lyophilic symmetrical membrane C, an ultrasound generator 7 is placed, which provides the effect of ultrasonic waves in the frequency range m-5-25 kHz with an intensity of 2.4 W/cm? on water in the membrane pores. The operation of the device begins by filling one part of it, for example, with seawater 1, and the second part with fresh water 2. Next, the electrode b is turned on to form a stationary inhomogeneous electric field, an arbitrary flow of water molecules from the volume with seawater 1 to the volume it with fresh water 2. Next, turn on the ultrasound generator 7, increase the power of the electric field and obtain desalinated water in an intensive version. The desalinated water is drained into the storage tank through the nozzle 9.

Sources:. 1. Vasylchenko A. New technologies in the construction of oil and gas wells / A.

Vasylchenko - Zaatbgykep: | AMVEVT Asadetis Rybiivpino, 2012. - 104 p. because 2. Sound radiation pressure. re: /Lymlu. uoshire.sot/maisp?m-10MgmyNruiom.

3. Konovalov E.H.

Scientific discovery Mo 109 dated May 31, 1961.

Claims (1)

USEFUL MODEL FORMULA A method of arbitrary liquid purification, which consists in the formation of ordered flows of solvent molecules in the pores of a semipermeable lyophilic membrane, the asymmetry of the solvent in the pores of which is provided by the formation of a gradient of structural organization, and the arbitrary movement of these flows is directed according to the gradient of structural organization into a volume with clean solvent, as well as in the implementation of the intensification of arbitrary flows of the solvent due to the action of a non-uniform electric field and ultrasonic waves on the magnitude of the gradient of the structural organization of the solvent in the pores of the specified semi-permeable lyophilic membrane, which is distinguished by the fact that the arbitrary purification of the liquid is carried out in the pores of the semi-permeable symmetrical lyophilic membrane, and the asymmetry in the system, the gradient of the structural organization of the solvent in the pores of the semipermeable symmetric lyophilic membrane and the formation of arbitrary liquid flows corresponding to this gradient are created by the preliminary action of an inhomogeneous electric of the field of the electrode, located on the side of the exit of the purified liquid from the membrane, on the liquid in the pores of the semipermeable symmetric lyophilic membrane, and the subsequent intensification of the resulting flow is carried out by increasing the power of the electric field and the action of ultrasound on the liquid in the pores of the membrane. 7 3 9 and Tychyny 1 i - 553, Sh - ; -El.-, 6 - 2 -- WHAT --» Where -0-k -k , - 2 - in -R -6e 2 sho: re Y YN these) --- Ч - o6. - 8 Fig. 1 year Z Ot no n 3 Fig. 2 and yuki r nn 2 A DSS Kosovek AI 3 Fig. 3