RU2518060C2 - Electric energy accumulating method and device for its implementation - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention is related to accumulation of electric energy generated by conversion of wind mechanical energy, energy of solar batteries, geothermal energy of heat sources, etc. This electric energy accumulating method lies in that accumulation is made by a non-mechanical way, to this end thixotropic dispersed system is prepared of ferromagnetic particles dispersed in liquid or solid phase of non-magnetic material, then the system is placed to a body with a magnetising mechanism, a magnetic field is generated, the thixotropic dispersed system is activated and the accumulator is charged up to the maximum value. The device for implementation of the above method includes a body connected to the direct-current source, inside the system there is a thixotropic dispersed system is prepared of ferromagnetic particles dispersed in liquid or solid phase of non-magnetic material, a magnetising mechanism which is represented by a solenoid connected to the direct-current source, and the solenoid axis is parallel to the body horizontal axis. Besides, the above device includes the magnetising mechanism made as at least two solenoids interconnected in parallel and placed above each other, at that the first and the last solenoids are connected to the direct-current source.

EFFECT: increasing service life and operational life of accumulator due to exclusion of chemical interaction of the electrolyte and electrodes and non-availability of electrodes destructed chemically.

3 cl, 3 dwg

Description

The invention can be used to accumulate electrical energy obtained by converting the mechanical energy of the wind, solar panels, geothermal energy of heat sources, etc.

A known method of accumulating electrical energy using lead, nickel-cadmium and other batteries (by chemical means).

This method is embedded in the charging-discharging process of a known lead-acid battery, on the down conductors of which the active material of bipolar electrodes is applied, bipolar electrodes are separated by separators, assembled into blocks, installed in a housing with an electrolyte. (RU 2050644 C1, IPC Н01М 2/18, published on December 20, 1995).

This method is also incorporated into the charging-discharging process of a known nickel-cadmium battery, including a package of electrode plates with separation of the positive and negative electrodes by separators, mounted in a battery case filled with electrolyte (RU 2336605 C1, IPC Н01М 2/18, published on October 20, 2008 g.).

The method of storing electrical energy using the above devices is based on a chemical method of storing electric energy. A disadvantage in the operation (charging-discharging) of these batteries is the chemical interaction of the electrodes with the electrolyte. As a result of chemical dissolution of one of the electrodes in the electrolyte, the service life and battery life are reduced.

Known electric battery containing a housing, an electrolyte, a block of electrodes with separators in the form of rods located at a distance equal to the thickness of the electrodes and connected at the top by a bar (SU 1480692 A1, IPC Н01М 2 /, 18, publ. 12/27/1995).

The disadvantage of this battery is the limited service life and service life.

Known lead battery adopted for the prototype, containing blocks of negative and positive electrodes, separated by separators and placed in a vessel filled with electrolyte (RU 2325013 C1, IPC HM 10/06, published on 05/20/2008). The basis of his work is the active chemical interaction of electrodes with an electrolyte.

The disadvantage of this battery is that a reactive electrolyte with respect to the electrodes destroys them with the formation of indecomposable sulfates on the surface of the electrodes. This reduces the resistance of the electrodes, limits the service life and service life of the batteries.

The purpose of the method of accumulating electrical energy and a device for its implementation is to increase the service life and service life of the battery by eliminating the chemical interaction of the electrolyte and electrodes and the absence of electrodes that are destroyed due to chemical reactions.

The technical result is achieved due to the fact that in the proposed method of accumulating electric energy, in contrast to the prototype, the accumulation is carried out non-chemically, for which a thixotropic dispersed system is prepared from particles of a ferromagnetic material dispersed in a liquid or solid phase of a non-magnetic material, and placed in a housing with a magnetization mechanism create a magnetic field, activate the thixotropic dispersed system, charge the battery to maximum capacity.

A device for implementing the method allows to achieve a technical result due to the fact that it includes a housing connected to a direct current source, but in contrast to the prototype, a thixotropic dispersed system of particles of ferromagnetic material dispersed in a liquid or solid phase of a non-magnetic material and a magnetization mechanism are located inside the housing, which is a solenoid connected to a direct current source, the axis of the solenoid is parallel to the horizontal axis of the housing.

In addition, in the device for implementing the method, in contrast to the prototype, the magnetization mechanism can be made in the form of at least two solenoids parallel to each other, placed one above the other, the first and last solenoids being connected to a direct current source.

It is known from the course of colloid chemistry that when an external magnetic field is applied in stable sols, suspensions, powders of dispersed ferromagnetic materials, the ferromagnetic particles are structured along the magnetic field. When removing the magnetic field, the initial state is restored (Schukin E.D., Pertsov A.V., Amelina E.A. Colloid chemistry. - M.: Moscow University Press, 1982. - 348 p.). Structuring and restoration of the position of particles in sols, suspensions, and powders of dispersed ferromagnetic materials, i.e., a change in the relative position of particles in a magnetic field, leads to the appearance of an emf in a closed loop of a solenoid that is located inside these colloids.

In the claimed invention uses a new non-chemical method of accumulating electrical energy in comparison with traditional methods, where the chemical interaction of electrodes with an electrolyte is used to accumulate energy.

The proposed method is based on the rheological properties of the dispersed system, due, in particular, to how independently particles can move in a dispersed medium from one another, that is, on the concentration, interaction, particle shape. Under certain conditions, particles in a dispersed medium tend to stick together, that is, at low concentrations, aggregates (flocculi) of particles arise.

With the collision of aggregates, as well as with their penetration into neighboring layers, aggregate destruction can occur. This leads to the appearance of non-Newtonian properties in a disperse system. Thus, the interaction (aggregation) of particles, which prevents their free transfer by layers of a moving fluid, has the most significant effect on the rheological properties of the system, that is, it fixes the relative position of the particles. In colloid chemistry, the phenomenon of fixing the spatial position of particles due to the appearance of bonds between them is called the structuring of a dispersed system. The reversible destruction and restoration of bonds between particles in a structured dispersed system is called thixotropy, and structured dispersed systems with such properties are called thixotropic. The destruction of bonds between particles with the potential nature of their interaction means the removal of particles from each other at a certain distance, which is possible immediately for all or most particles only in the presence of free volume, that is, the structural grid should be openwork. In structured disperse systems, the bonding of particles in a network is stronger than in colloidal solutions. All things being equal, all kinds of forces between the particles, and therefore the potential of the molecular-electrostatic pair interaction of particles, are proportional to the radius of the particles. This connection should be greater, since the cohesive forces of the particles resist not only thermal motion, but also the gravitational field.

In the process of preparing structured dispersed systems, it is necessary to proceed from the following. Structuring increases the viscosity of the suspension and in proportion to it, with stirring, stresses in unresolved formations increase, which leads to their intense destruction and a further increase in the density of the structural network, and hence to an increase in viscosity, progressive destruction of formations. In this regard, at the stage of preparation of the suspension, it is advisable to increase the concentration of the dispersible powder with the addition of solvent as the mixture is ground. The uniformity of structured dispersed systems is provided by thickening the dispersed medium. As a thickener, polymer solutions are used: polyisobutylene and others. The mechanism of action of the thickener is reduced to structuring the medium. Particles of the suspension, more coarsely dispersed components of the system, are then passively interspersed in the structured medium, that is, they can act as an active filler of the structured dispersed system. The introduction of a filler enhances the structural and mechanical properties of the system. In this case, particles on structured dispersed systems play the role of a suspension of ferromagnetic materials. With the same particle size, their domain structure depends on the nature of the ferromagnet. These materials include barium hexaferrite BaO 6 Fe ₂ O ₃ and gamma iron oxide g-Fe ₂ O ₃ .

This is due to the ability to change the interaction between particles and the structure of the system using a magnetic field, the complete determination of the structure of dispersed ferromagnets. The process of magnetization of multidomain particles of dispersed ferromagnets is caused by a shift in the interdomain boundaries inside the particle. In this case, the size of regions grows, the direction of magnetization of which coincides with the direction of the external field, and the size of other domains decreases accordingly. If the particles are single domain, then the main role is played by a change in the direction of the magnetization of the particle, that is, the direction of its magnetic moment. The possibility of changing the orientation of the particle under the influence of the field acting on the particle is determined by three factors: the energy of the magnetic anisotropy of the particle, the intensity of the rotational diffusion of the magnetic moment, and the structural and mechanical properties of the system. In sols of ferromagnets, this is easily accomplished, since the magnetization of the stable fluidity of a ferrofluid is limited by the value I = (7.7-10) 10 ⁴ A / m.

In an external field, that is, when particles are magnetized, the relative position of the particles is energetically most beneficial when their dipoles are parallel and lie on a common line passing through the centers of the dipoles. In sols and suspensions, this leads to the formation of chains oriented along the field. The peculiarity of this structure is that it is not continuous, like coagulation networks.

The cause of structure formation is, first of all, in the polydispersity of the system. The presence of a large particle in the chain creates a large magnetic flux, for saturation of which two or more chains of small particles are attached to it. The anisotropy of the structure is preserved, it becomes three-dimensional.

Therefore, the main cause of structure formation is the magnetodipole interaction of particles of a ferromagnet (Bibik EE, Matygullin B.Ya. Magnetostatic properties of colloidal magnetites. Magnetic hydrodynamics, - 1973. - No. 1. - p. 68-72).

Example. The preparation of a thixotropic dispersed system from particles of a ferromagnetic material dispersed in the solid phase of a non-magnetic material is as follows. Magnetic powder BaO 6 Fe ₂ O ₃ is mixed with a liquid base - kerosene and surfactant - oleic acid, the content of which is 10-20% of the volume of the base. After loading 0.2 kg / l of magnetic powder into the housing, it is milled for 2-3 hours.

The powder obtained after grinding is dispersed by ultrasound for 20 minutes at a frequency of 17 kHz. As a result, the particle diameter of the magnetic powder is 50-90 nm, the concentration of 10 ¹⁶ g / cm ³ .

The magnetization mechanism is designed by winding a copper wire with a diameter of 0.5 mm on a rigid frame with a diameter of 50-60 mm, which is then removed. The solenoid is placed in a rectangular case, which 70-80% of the volume is filled with the prepared dispersed ferromagnetic system. After that, the solenoid is connected to a DC source with a voltage of 10-12 V, a current of 1.2 A and a magnetic field of H = (5-6) 10 ^-5 A / m is created. The resulting magnetization curve corresponds to saturation at H = 6 · 10 ^-4 A / m. This value of the field corresponds to the saturation magnetization. Over a period of 200 seconds, the specific susceptibility changes from 1.8 to 0.6 and the volume from 20 to 15 cm ³ . Thus, within 3-4 minutes, the average number of neighboring particles in a thixotropic dispersed system increases by more than two, which is sufficient for the formation of a three-dimensional network of ferromagnetic particles in the volume of the suspension inside the solenoid. Thus, the battery is charged.

To implement the method, a device is proposed that includes a housing, a direct current source, a thixotropic dispersed system of particles of ferromagnetic material is filled in or filled in, dispersed in a liquid or solid phase of a non-magnetic material, a magnetization mechanism installed inside the housing, which is a solenoid whose axis is along horizontal axis of the housing, parallel to its lower part, and the solenoid is connected to a constant current source.

In addition, to implement the method, a device is proposed in which the magnetization mechanism is made in the form of at least two solenoids connected in series, arranged on top of each other parallel to the lower part of the housing, the first and last solenoids being connected to a direct current source.

Figure 1 schematically shows a General view of the battery, figure 2 - battery when charging, figure 3 - battery during discharge.

In figure 1, 2, 3 are indicated: 1 - housing, 2 - magnetization mechanism in the form of a solenoid, 3 - thixotropic dispersed system of particles of ferromagnetic material, 4 - housing cover, 5 - stops.

The battery (charge-discharge) is as follows.

The open housing 1 (FIG. 1 and FIG. 2) is filled to 70-80% of the volume with the prepared dispersed ferromagnetic system. Then the magnetization mechanism is lowered into it - the solenoid 2, which is fixed on the cover 4 with the help of stops 5. After that, the solenoid is connected to a DC source with a voltage of 10-12 V, a current of 1.2 A and a magnetic field N = 6 · 10 ^{is created - 5} A / m. As a result of the activation of the thixotropic dispersed ferromagnetic system, the system is structured along the direction of the magnetic field strength of the solenoid, that is, the battery is charged.

When you disconnect the battery (figure 3) from a constant current source, the process of demagnetization of the thixotropic dispersed ferromagnetic system. When the battery is disconnected from the direct current source, the magnetization of the ferromagnetic particles decreases, as a result of the thixotropic properties, the system returns to its initial unstructured state, i.e., the ferromagnetic particles move in the solenoid in the opposite direction. In so doing, in the solenoid 2 the emf of the opposite direction is induced, the current goes in the opposite direction. In this case, the battery is discharged.

The operation of the magnetization mechanism in the form of at least two solenoids parallel to each other, arranged one above the other, when the first and last solenoids are connected to a direct current source, is as follows. When charging the battery, a solenoid connected in series to a dispersed ferromagnetic system is connected to a constant current source. Each of the solenoids independently activates the ferromagnetic system, and when they are connected in parallel, the battery capacity is added up. When discharged, processes occur in the opposite direction.

Since in the inventive battery there are no chemical processes, the battery life is practically unlimited.

In traditional oxide-nickel and oxide-cadmium batteries with a capacity of 60-73 A / h, the number of charge-discharge cycles is 7200-10600, the operating time is from 6 to 8 months.

Claims (3)

1. The method of accumulation of electrical energy, characterized in that the accumulation is carried out non-chemically, for which a thixotropic dispersed system is prepared from particles of a ferromagnetic material dispersed in a liquid or solid phase of a non-magnetic material, placed in a housing with a magnetization mechanism, create a magnetic field, activate a thixotropic dispersed system, charge the battery to maximum capacity. 2. The device for implementing the method according to claim 1, comprising a housing connected to a direct current source, characterized in that a thixotropic dispersed system of particles of ferromagnetic material dispersed in a liquid or solid phase of a non-magnetic material, and a magnetization mechanism, which is a solenoid connected to a direct current source, the axis of the solenoid is parallel to the horizontal axis of the housing. 3. The device for implementing the method according to claim 2, characterized in that the magnetization mechanism is made in the form of at least two solenoids parallel to each other, placed one above the other, the first and last solenoids being connected to a direct current source.

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