CS213834B1 - Method of making a field of force visible,and recording the visible image thereof - Google Patents

Abstract

A method of visualization and recording of visible representation of a vectorial field on a carrier consists in heating the carrier to a temperature higher than the softening temperature of a binder (3) and placing the carrier into a vectorial field under the influence of which, particles (4) of the carrier, capable to change their spatial orientation within the binder (3), ensure the visualization of that vectorial field in the plane of the carrier. Recording of the visualized representation of the vectorial field is effected simultaneously with its visualization. The image is fixed by way of cooling the carrier (3) to a temperature lower than its softening temperature.

Description

(54) Force Field Visibility and Force Field Visible Recording *

The invention relates to a method of visualizing a force field and recording a visible force field image on a field sensitive layer, wherein the field sensitive layer is arranged in a force field and particles contained in the binder change their spatial position under the force field field sensitive layers.

The visualization and recording of visible force field images are used in particular and in particular for defectoscopy of materials, to check the quality of recording on magnetic tapes, to tear out magnetic recording devices, as well as in non-destructive testing of complicated electronic devices.

Continued use of known methods of visualizing and recording a visible force field image is hindered by the time-consuming and laborious practice of these methods since the visualization and recording of visible images are performed separately and an expensive silver-containing carrier is used for photography.

A known method of visualizing a magnetic or electric field is by the object being examined being sensed in a separate chamber by an electron beam. The energy of the scanning and reading beams is not great, and as a result a portion of the electrons arrives at the anode of the electron multiplier built into the chamber by the force field of the test item. The output signal of the electron multiplier changes according to the intensity field of the object at each point. A signal is transmitted from the electromic multiplier to the screen and an image of a power po213 834 is observed on its screen.

213 834 le of the surveyed objects. Recording of the visible image and · usually performed from the screen by shooting on a carrier containing silver. However, this method of visualizing the force field and recording it is expensive and requires special, complicated and expensive instruments for its realization.

There is also a known magneto-optical method of visualizing magnetic fields by rotating the polarization plane of the transmitted light - Faraday effect, or the reflected polarized light - Kerr effect, from magnetic thin layers that consist of cadmium-iron, terbium-iron alloys or ferrite garnet and they are arranged in a magnetic field. The angle of rotation of the polarization plane is proportional to the magnetization of the magnetic film. In this method, the object to be examined is arranged near or in contact with the magnetic film. The magnetic film is illuminated with polarized light and the megnetic field image of the test item is viewed through an eyepiece and a polaroid analyzer in reflected polarized light or in polarized light transmitted by the magnetic film. The change in the polarization of light caused by the anisotropy of the magnetic film under the magnetic field of the test item will be reflected as a change in the light intensity. The visible image of the force field is recorded photographically on a carrier containing silver, which is then developed and stabilized in a known manner. This magnetic way of visibility is also complicated in terms of technology and also requires special devices for its realization.

In another known method of visualizing the force field and recording a visible image of the force field on the carrier, the carrier is arranged in a force field in which the carrier particles placed on the substrate are spatially displaced, respectively, by the force field. it changes its space position and thus the force field is visible in the plane of the substrate. The visible image of the force field made in this way is recorded.

Recording is performed on photographic film, which is then developed and stabilized. This so-called powder image imaging method is based on the application of ponderomotor forces to electrically charged particles in the force field, or particles forming a dipole. The force of ponderomotor forces acting on electrically charged particles in an electric field is proportional to the particle charge and the field strength. Due to the ponderomotor forces, the finely divided particles change their position in space so that the density of the particles in the plane of the carrier substrate corresponds to the distribution of the inhomogeneities of the force field, the fine powder thus forming a visible image. This converts the force field inhomogeneity by means of a fine powder into optical inhomogeneities, which make the force field visible.

However, this method of visibility cannot provide a sufficiently contrasting image of the force field. The image produced is sensitive to mechanical disturbances that lead to powder powder and distortion of the image. Image recording created in this way is very time-consuming and very laborious and requires the use of a silver-containing carrier.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a method of visualizing a force field and recording a visible force field image onto a carrier, wherein the use of a silver-free carrier enables simultaneous visualization and recording of the visible force field circumference. further edit.

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This task is diluted by a method for visualizing a force field and recording a visible force field image on a field sensitive layer, in which the field sensitive layer is arranged in a force field and particles contained in the binder change their spatial position under the force field. in the plane of the field sensitive layer according to the invention, the field sensitive layer before or after its arrangement in the force field is heated to a temperature that is higher than the softening temperature of the binder containing the particles uniformly distributed therein, wherein the particles change their spatial position in the binder under the action of a force field, and upon cooling the binder to a temperature below the softening point, form a visible image of the force field.

This proposed method of visualizing the force field and recording the visible image of the force field on the field sensitive layer allows simultaneous visualization and recording on one and the same sensitive field layer, while the labor and time consuming for recording ae is reduced. Using this method, a contrasting and highly visible visual image of the force field on a silver-sensitive field layer is obtained, which allows a long storage time of the recorded and mechanical-resistant image. The method is technologically simple and does not require complicated and expensive devices.

The invention will be explained in more detail below with reference to the specific embodiments shown in the drawing.

FIG. 1 shows a field-sensitive layer made according to the invention and arranged near the permanent magnet, the particles of which are oriented along the field lines of the permanent magnet.

FIG. 2 shows a field sensitive layer made in accordance with the invention and arranged in a magnetic tape section, the particles of which are oriented along the field lines of the magnetic tape.

The method of visualizing the force field and recording the visible image of the force field is realized by means of a field sensitive layer 2 which is provided on the substrate 1 / FIG. 1 /. The field-sensitive layer 2 consists of a binder 3 and fine dust particles 4 distributed uniformly throughout the binder 3 volume, the only dust particles 4 having a dipole moment, possibly receiving or receiving an electric charge in the force field. Magnetic substances or electrets are used to form the particles 4. The binder used is a substance or a binder. substances which do not exhibit any chemical interactions with the particles 4, namely waxes, paraffins, resins, temoplastic polymers. The proposed method consists in heating the field-sensitive layer 2 to a temperature which is above the softening point of the binder. The viscosity of the binder is thereby reduced to a value at which movement of the particles dispersed therein is possible.

Thereafter, the field-sensitive layer 2 and the treatment on the substrate 1 are introduced into the force field of the test item or into the magnetic field of the permanent magnet 5. In the magnetic field, the particle 4 changes its spatial position under ponderomotor forces. of the object, i.e. the permanent magnet, whereby these inhomogeneities of the magnetic field of the test object are converted into optical inhomogeneities of the light-sensitive layer 2.

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In this case, the formation of the visible image of the force field is dependent on whether the light-sensitive particles 4 of the layer 2 have a dipole change or single sign charges.

The intensity of the ponderomotor force acting on one charged particle 4 in the electric field is proportional to the field intensity at the particle location 4, while the intensity of the ponderomotor force acting on the electrically or magnetically polarized particles 4 in the force field is proportional to the field intensity gradient at the particle jU. This will make the force field created by the object under investigation visible and simultaneously record the visible image of that field on one and the same field sensitive layer.

Thereafter, the field-sensitive layer 2 on the substrate 1 is cooled to a temperature which is below the softening point of the binder 3. The viscosity of the binder 3 rises and the particles 4 cannot change their spatial position due to ponderomotor field forces. This stabilizes the force field created by the object under investigation and whose visible image is recorded on the carrier.

A variant of the method is possible in which the substrate 1 with the field sensitive layer 2 * intended to visualize the force field and to record its visible image is first inserted into the force field of the test item and heated in this force field to a temperature above the softening point The visualization of the force field of the object under investigation and the recording of a visible image of this force field are performed simultaneously. To stabilize the recorded image, the field sensitive layer 2 is cooled to a temperature below the softening point of the binder 3.

On the field sensitive layer 2 used to visualize the force field and to record its visible image, the recording and deletion of the image can be performed multiple times. Deleting the recorded image and preparing the field sensitive layer 2 for new recording ae is carried out in a known manner, for example by heating to a temperature higher than the softening temperature of the binder 3 mixing the particles with an external swirl field or ultrasound and .

By using a substrate 1 with a field-sensitive layer 2 that contains finely divided dipole refractive particles 4 and having a thickness that is commensurate with the carrier width or length, it allows the visible and recording of spatial visible images of the force field of the test item corresponding to the inhomogeneities of the force field in space in which the arranged layer 2 is field sensitive. In order to visualize the received image, cuts are made in the field-sensitive layer 2 in those planes in which the distribution of the force field gradients is to be determined.

Below are examples of how to realize a force field visibility and record its visible image on a field sensitive layer 2.

Example

1. To obtain a visible image of the force field, use is made of a carrier comprising glass substrates (FIG. 1) with a thickness of 100 µm on which a 30 µm thick field sensitive layer 2 lies. The field sensitive layer 2 comprises a binder 3 consisting of polytrimethylene pimelate at a softening temperature of 60 ° C and particles of needle-shaped 4 dispersed therein

213 834 of ferrogranate Y2FE4 * Alq ^{0 in the} range of 2 to 5 pa at a concentration of 15% volume. On the field sensitive layer 2 there is a protective layer 6 of cellulose triacetate.

The field-sensitive layer 2 on the substrate 1 is placed in the magnetic field of the permanent magnet 5 and heated up to a temperature of 65 to 70 ° β. The heating is carried out by an electric current which is guided by the electrodes 7 in the form of strips. The electrodes 7 are formed from an electrically conductive and translucent indium oxide film which is precipitated on the glass substrate 11 and is located between the substrate 1 and the field sensitive layer 2. Due to the ponderomotor forces of the magnetic field of the permanent magnet 5, the density of the particles 4 is arranged so that it corresponds to the distribution of the inhomogeneities of the magnetic field. In this way, the inhomogeneities of the magnetic field are converted by means of finely divided magnetic particles 4 into the optical inhomogeneities of the field-sensitive layer 2, and thus also the visualization of the force field and its visible image is achieved. Thereafter, the field sensitive layer 2 is cooled to a temperature below 60 ° C, i.e. below the softening point of the binder 3, thereby stabilizing the received image.

2. To produce a visible force field image, a film substrate 1 of polyethylene terephthalate 60 µm thick is used, which carries a 10 µm field sensitive layer 2. C, in which needle-shaped particles 4 of ferromagnetic spinel Zn _{0> 72} Ni _{0 | 28} Fe ₂ 0 _{4 0 are dispersed in dimensions up} to a concentration of 20 o / o volume * of cellulose triacetate.

The field-sensitive layer 12 is heated to a temperature of 40 ° C which is higher than the softening temperature of the binder J. The heated field-sensitive layer 2 is inserted into the force field of the magnetic tape 8, on which a 1 MHz signal is recorded. wherein the recording wavelength is 40 µm, by the ponderomotor forces of the scattered field of the signal recorded on the magnetic tape, the particles 4 are arranged according to the scattering field of the signal. On the field sensitive layer, the following light and dark bands appear periodically in succession. Equilibration is accomplished by cooling the carrier to a temperature below 38 ° C, i.e. below the softening point of the binder 3.

Claims (1)

PREFACE OF THE INVENTION A method of visualizing a force field and recording a visible force field image on a field sensitive layer, wherein the field sensitive layer is arranged in a force field and the particles contained in the binder change their spatial position under the force field thereby providing visibility of the force field in the plane of field, characterized in that the field-sensitive layer (2) before or after its arrangement in the force field is heated to a temperature that is higher than the softening temperature of the binder (3) containing the particles (4) uniformly distributed therein , wherein the particles (4) change their spatial position in the binder (3) under the action of a force field, and upon cooling the binder (3) to a temperature below its softening temperature, a visible image of the force field is formed.