RU2123736C1 - Nonmagnetic material magnetizing technique - Google Patents

Abstract

FIELD: electrical engineering, medicine, building engineering. SUBSTANCE: material is irradiated by external magnetic field source made in the form of set of current-conducting strips placed on insulating substrate folded in the form of MФbius band. Conducting strips are provided with output terminals. Magnetizing time is inversely proportional to product of magnetizing material thickness by specific weight. EFFECT: facilitated procedure. 2 dwg

Description

 The present invention relates to the field of magnetic processing of non-magnetic materials used, for example, in construction equipment.

 Known methods for magnetizing non-magnetic materials / plastics, rubber, glass, etc. /, based on the use of electrically conductive media, such as water, which is magnetized using specialized means. [cm. V.I. Klasen. Magnetization of water systems, ed II-e. - M.: Chemistry, 1982, p. 19 - 1].

 A disadvantage of the known methods is that water loses its magnetic properties after a few days.

 The means of magnetization are presented, depending on the task, the requirements for creating a specific configuration of magnetic fields with a change in the gradient of tension according to a predetermined law.

 A known method of magnetic treatment of a liquid with a spiral screw feed through a workspace irradiated with a magnetic field, namely, that the salt composition is removed axially through an area with a smaller cross section relative to the cross-sectional area of the spiral flow [see A.S. USSR N 313778, class C 02 F 1/48 - 2].

 Effective processing in a wide range of salt composition is possible only with optimal values of the magnetic field strength, speed and the number of times the fluid crosses magnetic fields of alternating polarity.

 In addition, a significant drawback of the known method is the incomplete use of the magnetic field and the need to regulate processing modes, which cannot be carried out promptly even with continuous monitoring of the salinity of the liquid, because the magnetic field is not linearly dependent on salinity, and there are no methods for indicating the effect of magnetic treatment that quickly and reliably evaluate the effect under operating conditions.

 A known method of magnetizing a liquid using a device that allows for efficient processing by creating a smooth change in the gradient of the magnetic field [see A.S. USSR N 850154 C 02 F 1/48, B.I. N 28, 81 - 3].

 The magnetization means comprises a cylindrical housing with inlet and outlet nozzles with a solenoid located outside the housing and a core installed inside the housing, as well as an additional solenoid, the core being made in the form of a piston.

 There is also a method of activating building mixtures, which can be considered as a prototype [and.with. USSR N 392024 C 02 F 1/48 - 4], which consists in exposing them to a magnetic field, which is carried out in sequentially arranged, rotating in opposite directions magnetic fields, in the zones of action of which ferromagnetic bodies are placed, for example, cylindrical.

 The disadvantage of this method lies in the fact that the mortar remains active only for several days, i.e. the operational capabilities of such a mixture are limited.

 The technical result from the use of the proposed technical solution is to expand operational capabilities by increasing the shelf life of the properties to infinity, acquired as a result of magnetization.

 To achieve a technical result in accordance with the proposed method based on the interaction of a non-magnetic material with an external magnetic field source, an external magnetic field is initiated by a source in the form of a system of conductive strips located on a dielectric substrate rolled in the form of a Moebius tape, conductive strips are equipped with output terminals located on the inner and outer sides of the surface of the Moebius band opposite each other, while the magnetization time is inversely proportional to the product of tires magnetisable material the specific weight.

 Currently, the applicant from the analysis of all types of information publicly available in Russia does not know the methods in which there is a combination of features that are distinctive in the stated decision, i.e. The proposed technical solution is new.

 The inventive method has an inventive step, because it does not explicitly follow from the prior art for a specialist. The author carried out theoretical and experimental studies, which allowed to identify the distinguishing features of the method, ensuring the achievement of a technical effect.

 In FIG. 1 shows a schematic of the source device with which the proposed method is implemented. As seen in FIG. 1, the magnetized sample 1 is located at some distance from the magnetic source 2.

 In FIG. 2 shows a magnetic source in cross section.

 As seen in FIG. 2, the source contains a system of conductive strips 3 located on a dielectric substrate 4, rolled up in the form of a Moebius strip, while the conductive strips are equipped with output terminals 5, 6 located on the inner and outer sides of the surface of the Moebius strip opposite each other.

 The physical concepts underlying the proposed method are as follows.

 The natural phenomenon of ball lightning is known, which, according to current hypotheses, is the result of vacuum polarization. The formation of ball lightning is associated with the existence of particles generated under certain conditions, called monopoles. Ball lightning, i.e. magnetic monopoles were obtained in the laboratory from a vacuum polarization source described in patent application N 4841331 dated May 21, 1990, according to which a positive decision was obtained on the grant of a patent dated August 8, 1991.

 The basis of the proposed method is the interaction of the fields of a particular source, consisting of magnetic monopoles, with non-magnetic material. It is assumed that the magnetic monopoles emitted by the source get stuck in the substance, and the substance from the diamagnet turns into a para- or ferromagnet.

The proposed method is specifically implemented as follows:
a sinusoidal voltage with an amplitude of about 12 V at currents of about 200 A at a frequency of 0.01 Hz to 200 KHz or a pulse voltage with an amplitude of 1.5 - 3 V at currents of 6 - 10 kA with a repetition rate of 50 Hz is supplied to the source terminals. Magnetized samples are located from a source of magnetic monopoles at a distance of 0 to 5 or more meters, depending on the thickness of the sample and the density of the material from which it is made.

 In laboratory conditions, work was carried out to magnetize non-magnetic materials.

 Samples from plastic materials such as polymethylmethacrylate, polyethylene, fluoroplastic, epoxy resins, polyurethanes, polycarbonates, rubbers, glasses of type C-52 were used as magnetizable samples; N 23; II-15; C-5, ceramics 22xC, alunda.

 The results of the analyzes are shown in the table.

 In the process of studying the effect of the magnetic field of the source of monopoles on the magnetic parameters of substances, it was found that the greatest induced magnetic susceptibility is observed in those substances that have in their composition the largest number of oxygen atoms, which is paramagnetic.

 It is empirically established that the optimal processing zone for film materials is the spherical region surrounding the device with a radius equal to five widths of the dielectric base of the device. In this zone, dielectrics can be drawn at a speed of 0 to 30 m / s without degraded magnetization quality. In the rest of the surrounding space in the spherical region from five widths of the dielectric base of the monopole source, at least up to 100 materials can be magnetized in a compact form in pieces, blocks, etc., moreover, for magnetization in this case it takes longer than for film . The magnetization time is approximately inversely proportional to the product of the thickness and the specific gravity of the material.

 During the durability tests, it was found that the magnetization of the samples does not disappear, at least during the year when stored at room temperature.

All magnetization experiments were carried out with a monopole source manufactured in laboratory conditions with the following parameters:
- the dielectric base is made of lavsan, 60 mm wide and 100 microns thick;
- conductive tracks of aluminum Al, 10 mm wide and 10 microns thick;
- the gap between the tracks is 1 mm.

 The present invention can be used in electrical engineering, medicine, construction.

Claims (1)

 The method of magnetization of non-magnetic materials, in which the latter is placed in the magnetic field of the source, characterized in that as the specified source using a system of conductive strips located on a dielectric substrate, rolled in the form of a Moebius strip, the conductive strips are equipped with output terminals located on the inner and outer sides Moebius surfaces are opposite to each other, while the magnetization time is inversely proportional to the product of the thickness of the magnetized material by the specific gravity.

Images