RU2402828C1 - Method of preparing magnetosensitive suspension for viewing magnetic fields for recording and magnetic-tape testing - Google Patents

Abstract

FIELD: physics. ^ SUBSTANCE: to prepare magnetosensitive suspension, magnetic liquid of the magnetite type in kerosene is dried for a long period of time at room temperature. The crushed dry residue is added to water, after which ultrasonic dispersion is carried out while adding a surfactant (sodium oleate) to prevent coagulation. A thin layer of the magnetosensitive suspension is deposited onto a magnetic recording medium. The effect of the uniform magnetic field gives rise to ponderomotive forces acting on the magnetised particles. The latter move in the direction of increase of magnetic induction, i.e. are pulled and fall in the region with a stronger field, which can be viewed. During magnetic-tape testing, a thin layer of the magnetosensitive suspension is poured into a dish in form of an aluminium ring with diametre of 2 cm, attached to one side of the thin film. The dish is placed on the analysed ferromagnetic object which is magnetised by a permanent magnet. Magnetograms of the analysed specimens are viewed. ^ EFFECT: reduced material and time expenditure, increased stability, useful life and resolving power of the magnetosensitive liquid. ^ 2 cl, 3 dwg

Description

FIELD OF THE INVENTION

The invention relates to a control and measuring technique and can be used to visualize the magnetic fields of recordings during magnetographic inspection and ferrography.

State of the art

There are several methods for visualizing magnetic recording fields using magnetically sensitive liquids, as well as their use in flaw detection and ferrography (A.S. No. 1593484 V.I. Drozdova et al., A.S. No. 741137 T.Ya. Gorazdovsky, A. N. Fistun, V.V. Chekanov). The main indicator media capable of visualizing magnetic fields of recording or defects on the surface of products are: emulsions of magnetic fluids and magnetic fluids with micro-droplet aggregates. An important problem in the synthesis of such media is an increase in their coagulation and sedimentation stability, depending on the size of the droplets, interfacial tension, and the method of stabilization.

To visualize magnetic recording, the magnetized tape is coated with a layer of a magnetically sensitive emulsion or magnetic fluid with micro-droplet aggregates. Under the action of ponderomotive forces, the magnetic phase accumulates on the surface of magnetic signalograms. The resulting structure has a certain period, depending on the wavelength of the recorded signal. During defectoscopy, the droplets of the magnetic phase drift toward the magnetized object, since inhomogeneous scattering fields act on the suspended droplets of the magnetic fluid.

A magnetosensitive liquid allows you to visualize video signals with a maximum recording density of 2 · 10 ³ magnetization transitions per 1 mm (bp / mm), digital magnetic waveforms with a recording density of 700 bp / mm (G. Shagrova Methods of information control on magnetic media. - M. : Fizmatlit, 2005 .-- 193 p.).

The disadvantages of these methods is the lack of temporary stability of the indicator medium, as well as the low resolution of such media associated with the size of the droplets (more than one micron).

A known method of visualizing magnetic recordings (A.S. No. 989450 V.V. Chekanov, I.Yu. Chuenkova), which consists in the fact that the magnetized tape is coated with a layer of magnetic fluid, onto which a layer of non-magnetic fluid is applied and registration of the distribution of fluid in polarized the light. In this case, a surfactant is added to the non-magnetic fluid layer in an amount of 1-5 drops per 0.01 m ^{2 of the} surface of the magnetized tape.

When visualizing the recording of defects - cracks with a width of 1-3 microns - a curvature of the surface of the magnetic fluid occurs at the boundary with a non-magnetic radius of the order of several microns.

The main disadvantage of this method is the insufficiently high sensitivity.

The closest in technical essence and the achieved positive effect and adopted by the authors for the prototype is a method for visualizing magnetic fields of a recording using a magnetically sensitive liquid (A.S. No. 1633348 "Magnetically sensitive liquid for visualizing magnetic fields of a recording and method for its preparation", authors Dikansky Yu.I. ., Balabanov K.A., Polikhronidi N.G.), including applying to the surface of a magnetic tape placed on a microscope stage, a layer of magnetic fluid. When the temperature is lowered with a thermostat to a critical temperature, depending on the concentration of the magnetic fluid, aggregates are formed in the latter, which, under the influence of the magnetic field, of the signalogram move to the places of the inhomogeneous magnetic field on the surface of the magnetic tape and settle on them. The magnetic fluid used for this contains:

- magnetite - 18-20 vol.%,

- oleic acid - 2-3 vol.%,

- mineral oil - 40-47 vol.%,

- kerosene - the rest.

The magnetically sensitive liquid is heated to 40-50 ° C and mixed with an electromechanical mixer. After that, the mixture is divided into strongly and weakly concentrated phases by the sedimentation method for 7-10 days. The weakly concentrated phase thus obtained is used for imaging.

The disadvantages of this method include the complexity of obtaining magnetically sensitive liquids and the relatively low resolution associated with a fairly large (3-5 microns) sizes of aggregates. In addition, in such an environment, spontaneous formation of microdrops can occur over time, which reduces its storage time.

Disclosure of invention

The objective of the invention is the creation of a magnetically sensitive dispersed medium with greater sensitivity to magnetic fields and with a longer shelf life than magnetic emulsions, which makes it possible to use them more effectively for visualizing magnetic fields of recording and magnetographic defectoscopy.

The technical result is achieved using a method for producing a magnetically sensitive liquid, in which particles obtained by crushing the dry residue of the magnetic fluid after its evaporation are used instead of microdrops of magnetic fluid.

To obtain a magnetically sensitive dispersed medium, a magnetite type magnetite in kerosene is used, which is dried for a long time at room temperature. The crushed dry residue is added to water, after which ultrasonic dispersion is carried out with the addition of a surfactant (sodium oleate) to prevent coagulation. The study of the processes of structure formation in the system of such particles is carried out using an optical microscope, the field of view of which is displayed on a computer screen using a digital video camera, in addition, the presence of particles with a particle size of less than 1 μm in the fine fraction is studied according to the results of diffraction light scattering studies.

The essence of the method of preparation of a magnetically sensitive liquid for visualization of magnetic fields of recording and magnetographic inspection is as follows.

A small amount (10-20 ml) of magnetic fluid containing magnetite 15%, kerosene 82% and oleic acid 3%, on an easily volatile basis, placed in a Petri dish, is dried at room temperature for 72 hours. Magnetic fluids are a homogeneous colloidal solution of a ferro- or ferrimagnetic material in a non-magnetic carrier fluid. (Fertman EE Magnetic fluids. - Minsk: Higher school, 1988. - 184 s). The dry residue is ground in a mortar to obtain a powder, the particle size of which is controlled using an optical microscope. The average size of magnetic particles was 1-2 microns, with a duration of the process of crushing the powder of 10-15 minutes To obtain a powder with smaller particles, the duration of the crushing process increased to 1-2 hours. A small amount of powder (2-3 grams) is placed in a test tube with water, a volume of 10 ml, with the addition of 0.2-0.3 ml of sodium oleate to create coagulation stability. Dispersion of the resulting mixture is carried out in an ultrasonic bath. A thin layer of the obtained magnetosensitive suspension is applied with a brush to a magnetic recording medium. The action of an inhomogeneous magnetic field leads to the appearance of a ponderomotive force acting on magnetized particles, while the latter move in the direction of increasing magnetic induction, i.e. are drawn into the region of a stronger field, which is observed visually. Figure 1 presents photographs of magnetic recording on a magnetic disk (a) and on magnetic tape (b) used in devices for automatically recording flight parameters of the SARPP ("black box") of an IL-76 aircraft obtained after preliminary processing of the disk and film with the developed liquid (Photos taken using an optical microscope).

The obtained magnetosensitive liquid can also be used in flaw detection and ferrography. A thin layer (less than 1 mm) of a magnetically sensitive suspension is poured into a cuvette, which is an aluminum ring 2 cm in diameter, sealed on one side with a thin film. The cuvette is placed on the ferromagnetic object under study, magnetized with a permanent magnet. In this case, magnetograms of the studied samples are observed. Figure 2 shows the manifestation of polished numbers on a metal substrate, not visually observed, and figure 3 shows the manifestation of magnetization defects of a ferrite magnet used in instrumentation.

Brief Description of the Drawings

Figure 1 - a method of preparing a magnetosensitive suspension for visualizing magnetic fields of recording and magnetic flaw detection, in a photograph of a visualized magnetic recording on a magnetic disk (a) in the region "a" there is no magnetically sensitive liquid, liquid is applied to the region "b"; and on magnetic film (b) SARPP IL-76 aircraft increase 2x and 800x.

Figure 2 is the same, the manifestation of pre-polished numbers on the iron plate using the developed magnetosensitive suspension.

Figure 3 is the same, visualization of the defects of magnetization of a ferrite magnet.

The implementation of the invention

Examples of a specific implementation of the method of preparation of a magnetically sensitive liquid for visualizing magnetic fields of recording and magnetographic inspection.

, при этом последние перемещаются в сторону увеличения магнитной индукции, т.е. втягиваются и оседают в области более сильного поля, что и наблюдается визуально. На фиг.1 представлены фотографии магнитной записи на магнитном диске (а) и на магнитной ленте (б), используемой в устройствах автоматической регистрации параметров полета САРПП («черном ящике») самолета ИЛ-76, полученные после предварительной обработки диска и пленки разработанной суспензией (фотографии сделаны при использовании оптического микроскопа).Example. A small amount (10-20 ml) of magnetic fluid containing magnetite 15%, kerosene 82% and oleic acid 3%, placed in a Petri dish, is dried for several days (about 72 hours) at room temperature. The dry residue is crushed in a mortar to obtain a powder, the particle size of which is monitored using an optical microscope and by studying the diffraction light scattering of suspensions of such particles in a liquid. The average size of magnetic particles was 1-2 microns or less, depending on the duration of the process of crushing the powder. A few grams (2-3 g) of the thus obtained powder is placed in a test tube with distilled water (10 ml) with the addition of 0.2-0.3 ml of sodium oleate to increase coagulation stability. The tube with the resulting suspension is placed in an ultrasonic bath for 30 minutes to further disperse the suspension. A thin layer of the obtained magnetosensitive liquid is applied with a brush to a magnetic recording medium (magnetic diskette, magnetic tape, hard disk). The action of an inhomogeneous magnetic field leads to the appearance of a ponderomotive force acting on magnetized particles

, while the latter move in the direction of increasing magnetic induction, i.e. retract and settle in the area of a stronger field, which is observed visually. Figure 1 presents photographs of magnetic recording on a magnetic disk (a) and on magnetic tape (b) used in devices for automatically recording flight parameters of the SARPP ("black box") of an IL-76 aircraft obtained after preliminary processing of the disk and film with the developed suspension (Photos taken using an optical microscope).

Example. A thin layer (less than 1 mm) of a magnetically sensitive liquid is poured into a cuvette, which is an aluminum ring 2 cm in diameter, sealed on one side with a thin film. The cuvette is placed on the ferromagnetic object under study, magnetized with a permanent magnet. During the magnetization of the studied objects, the defects present in them lead to the appearance of scattering magnetic fields. Ponderomotive forces acting on suspended magnetic particles of a magnetically sensitive fluid lead to particles being drawn into a region of a stronger magnetic field near defects. In this case, magnetograms of the studied samples are observed. Figure 2 shows the manifestation of pre-polished numbers stamped on a metal substrate, and figure 3 is a visualization of the magnetization defects of a ferrite magnet.

Thus, the proposed method for the preparation of a magnetically sensitive suspension allows you to quickly, efficiently and simply prepare a liquid for visualizing magnetic fields of recording and magnetographic flaw detection.

The invention in comparison with the prototype and other known technical solutions has the following advantages:

- reduction of material and time costs;

- allows you to get a stable magnetosensitive fluid having a longer shelf life;

- the properties of the magnetically sensitive fluid are restored by simple shaking;

- higher resolution.

Claims (1)

A method of manufacturing a magnetosensitive suspension for visualizing magnetic fields of recording and magnetographic inspection, comprising a magnetically sensitive liquid for visualizing magnetic fields of recording containing magnetite 15%, kerosene 82% and oleic acid 3%, characterized in that it is dried at room temperature for 72 hours, with further crushing of the obtained dry residue in a mortar for 10-15 minutes, a suspension of which weighs 2-3 g in water, with a volume of 10-20 ml, is dispersed in an ultrasonic bath when added and sodium oleate in an amount of 0.2-0.3 ml per 10 ml of water.

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