RU2222055C2 - Magneto-inversion display panel - Google Patents

Abstract

FIELD: magnetic indicator panes with inversion of material. SUBSTANCE: invention is related to magneto-inversion indicator panel with inversion of material in which image is formed by inversion of magnetic displaying material with the aid of magnet and is erased by inversion of material on same side. Technical result of invention consists in development of indicator panel with inversion of magnetic material characterized by increased definition of image and its erasure from panel on which image is formed by inversion of magnetic material. This technical result is achieved as magnetic indicator panel with inversion of material has base carrying liquid dispersion characterized by certain value of yield point and containing in the capacity of key components magnetic displaying material in the form of thin particles which magnetic poles of opposite signs are differently colored by deposition of thin metal layer on one surface as minimum and fabrication of second surface in color different from color of thin metal layer on first surface, dispersive medium and thickening agent. Summary area of S poles or surface of N poles of magnetic displaying material in the form of thin particles amounts to 60% as minimum of area of displaying surface of indicator panel, or is equal to it or exceeds given area by factor of 15 and not more. Due to this magnetic indicator panel with inversion of material corresponding to proposed approach demonstrates good contrast range and makes it feasible to form image of metallic or pastel hue. EFFECT: increased definition of image and its erasure from panel on which image is formed with inversion of material. 15 cl, 6 tbl

Description

 The present invention relates to a magnetic display panel with material inversion, where the image is formed by inverting the magnetic display material using a magnet and erased by inverting the materials with a magnet from the same side. More specifically, it relates to a material inverted magnetic display panel in which the magnetic display material has magnetic poles of opposite signs painted in different colors by applying a thin opaque metal layer to at least one surface and making the second surface in a color different from the color a thin metal layer on the first surface.

 In a known magnetic display panel, fine particles of magnetic material are dispersed in a dispersion medium. The image is formed due to the migration of magnetic particles to the surface of the panel, which has a magnet. The image is erased due to the deposition of magnetic particles under the action of a magnet on the opposite side. For this type of magnetic display panel, the disadvantage is that the apparatus becomes complex and cumbersome, since image erasure must be performed from the back of the panel. In addition, when migrating magnetic particles to the panel surface, it is difficult to erase only an unnecessary part of the image.

Further, Japanese Patent Publication No. 59-32796 / 1984, which is incorporated herein by reference, proposes a magnetic display panel in which the indication is realized by inverting the imaging magnetic particles. This panel uses a liquid dispersion of magnetic particles with a residual magnetic moment of 0.2 to 10 electromagnetic units per gram and a coercive force of at least 500 Oersted; the yield strength of the dispersion is not less than 5.0 N / m ² .

 This panel, however, had such disadvantages as low contrast and fuzziness due to insufficient inversion when forming an image by inverting magnetic particles or erasing them.

 The purpose of the invention is to create a display panel with inversion of magnetic material, characterized by increased image clarity and its erasure from the panel, the image on which is formed by inverting the magnetic material. In particular, the liquid dispersion in the display panel has a certain yield strength and contains, as main components, a magnetic imaging material in the form of thin particles having opposite magnetic poles, painted in different colors by using a thin opaque metal layer at least one surface and giving another surface a color different from the color of the first surface, and also contains a dispersion medium and a thickener, and rests on the base. The ratio between the internal volume V of the base carrying the liquid dispersion and the volume W of the magnetic imaging material in the form of fine particles is W / V • 100 = 1 to 17%. The total surface area of the S-poles or surfaces of the N-poles of the magnetic imaging material in the form of fine particles dispersed in the liquid dispersion of the panel is from 60 to 1500% of the display surface of the display panel.

 Preferred Embodiments

 The magnetic imaging material used in the present invention is a magnetic material with magnetic poles of opposite signs, which are given shades of different colors by applying a thin opaque metal layer on one surface and giving the other surface a color different from the color of the first surface. The magnetic material is inverted under the influence of a magnetic field, forming an image. For example, when the S-pole of a writing magnet is drawn along the imaging surface of the panel, the surfaces of the N-poles of the magnetic material are arranged on the surface of the panel so that it acquires the color of the N-poles. When an N-pole of a magnetic pen is written over a surface, the magnetic material is inverted and the surface becomes the color of the S-poles. When the S-pole of the magnetic pen is again drawn across the panel, the material is inverted and the image disappears, so that a panel having the color of the metal and the color of the magnetic material is obtained.

 In the present invention, the ratio between the internal volume V of the base in which the liquid dispersion is located and the volume W of the fine-particle magnetic imaging material is W / V • 100 = 1 to 17%. When this ratio is less than 1%, the image tends to be blurry due to the small amount of imaging material, and when the ratio exceeds 17%, this makes it difficult to uniformly invert, since the particles of the material interfere with each other during inversion. The same volume ratio is preferred in cases where the magnetic imaging material is contained in a cell or capsule. The ratio between the internal volume V of one cell or capsule and the volume W of the magnetic imaging material therein should also preferably be W / V • 100 = 1 to 17%.

 Further, in the present invention, the total surface area of the S-poles or N-poles of the magnetic display material for obtaining a clear image should be from 60 to 1500% of the display surface of the display panel.

 The display surface area of the display panel means the flat surface area for forming an image on a panel containing a liquid dispersion in which the magnetic display material is dispersed.

 The authors of the present invention have found that one of the reasons for blurring the image in known display panels with material inversion is the mismatch between the surface area of the S-poles or N-poles of the magnetic material forming the image, and the area of the display surface of the panel. Another reason is insufficient inversion of the magnetic material.

 If the surface area of the S-poles or N-poles of the magnetic material forming the image is less than 60% of the area of the display surface of the panel, the color of the image becomes pale and the color difference between the color of the image and the color of the background substrate decreases, resulting in low contrast, and the image - fuzzy.

 On the other hand, if the surface area of the poles exceeds 1500%, then due to too much mutual interference caused by particles of the magnetic material, the inversion is difficult and there is non-inverted material on the surface, material turned outward by the boundary between the S-pole and the N-pole, and so on so that the image is a mixed color and therefore cannot be clear.

The liquid dispersion in which the magnetic imaging material is dispersed must have certain yield and viscosity values. A certain amount of fluidity is necessary for good dispersion of the magnetic material in the liquid dispersion, good inversion of it due to the influence of the magnetic field, and also to prevent the deposition of particles of the material. Viscosity is required so that only that part of the material that is affected by the magnetic field is inverted. More specifically, it is preferred that the liquid dispersion has a yield strength of 0.15 to 7.5 N / m ² and a viscosity of 3 to 350 mPa · s. An inorganic substance such as “AEROSIL” can be used as a thickener to impart a desired yield strength. However, inorganic thickeners have the disadvantage that their viscosity and yield strength change over time. In contrast, an organic thickener selected from fatty acid bis-amides, hydrogenated castor oil, and N-acylamino acid amides has the advantage that it provides the required yield strength, and the viscosity and yield strength hardly change with time.

In the case when the liquid dispersion has a yield strength and viscosity that go beyond the ranges of 0.15-7.5 N / m ² and 3-350 MPa • s, respectively, although the yield strength and viscosity are still acceptable, the stability of the preservation of the formed the image deteriorates, and due to the fact that when writing with a magnetic pen, material gathers around it, the distribution of the magnetic material becomes inhomogeneous, so that the color at the periphery of the image formed by inversion and the color of the background formed by non-inverted magnetic material in pyr image tend to vary. As a result, the image as a whole becomes blurry, that is, the clarity deteriorates.

 The magnetic imaging material used in the present invention has different surface colors of S-poles and surfaces of N-poles. An opaque thin metal layer should be applied to one of its surfaces, the specific appearance or shape of which is not significant. However, since it is necessary to form an image when writing with a magnetic pen, as well as the clarity of the formed image, it is preferable that the imaging magnetic material be obtained by dispersing magnetic particles in a composition containing synthetic resin and / or synthetic rubber of a certain color, and cutting or grinding the layered structure, obtained by applying a thin opaque metal layer, or so that the magnetic imaging material was obtained by creating a layered color Nogo leaf surfaces with various colors and cutting or shredding the laminated sheet obtained by applying an opaque thin metal layer on at least one surface. The color of the surface on which the opaque thin metal layer is not applied may be the color of the magnetic material itself, without coloring. Further, a color layer can be present on both surfaces or on the same surface, while a thin metal layer is applied on one surface.

 Alternatively, the surfaces of the S-poles and N-poles are painted in different colors and a thin transparent metallic layer is applied to both surfaces, so that the result is a metallic tone.

 According to studies by the authors of the present invention, the magnetic imaging material is inverted by the magnetic force of the opposite pole, and the particles of the magnetic material of a flat or film form are turned over in stacks, sliding along each other. Accordingly, such a material is preferable since not only the image forming speed is increased, but also a sharper image with a small amount of non-inverted or insufficiently inverted material is obtained.

 In particular, in the case when the particles of the magnetic imaging material have a flat or film shape, it should be noted that when the total surface area of the S-poles or N-poles is not less than 1500% of the display area of the panel, the inversion of the stacked material with sliding becomes insufficiently expressed, as they interfere with each other.

 The most preferred form of an opaque layer applied to the painted surfaces of magnetic particles is an opaque thin layer formed by vacuum deposition from the vapor phase.

 When there is an opaque thin metal layer on the magnetic display material, the image forms a combination of metallic luster and non-metallic luster, so that high contrast and enhanced image clarity are provided.

 Magnetic imaging material tends to be charged with static electricity due to friction between particles during inversion. Particularly, particles of a flat or film form are easily charged with electricity, since they are inverted in stacks, sliding along one another. Being electrostatically charged, the particles of the magnetic material stick together, so that their uniform inversion is difficult and some of the material is not inverted. As a result, a case may occur when it is not possible to obtain a clear image using a magnetic imaging material painted in various colors, so electrostatic charges should be avoided.

 As an antistatic agent, one or several substances can be used selected from polybutene sulfation products, quaternary salts of aliphatic alkyl ammonium bases, amino-ethanol-epichlorohydrin polycondensates, alkylbenzenesulfonic acids, metal salts of alkylsalicylic acid salts of metal sulfosuccinic acid sulfide salts of dialkyl salts. Particularly preferred are a mixture of polybutene sulfation products, quaternary salts of aliphatic alkyl ammonium bases, amino ethanol-epichlorohydrin polycondensates and alkylbenzenesulfonic acids, as well as a mixture of chromic salts of alkylsalicylic acids, calcium salt of sulfosuccinic acid and polymer.

 The base design for the liquid dispersion of the magnetic imaging material is not particularly limited, and the following can optionally be used: a base consisting of two substrates with a space between them, hermetically connected around the perimeter; a base in which cells in the form of cells are placed between such two substrates; a base in which capsules are placed on a substrate; etc.

 Examples of carrying out the invention.

 The following are examples of the present invention, although the invention is not limited to them.

Example 1
On a film of polyethylene terephthalate (PET) with a thickness of 25 μm, used as a base, a green magnetic paint was applied having the composition shown in table. 1; The preparation, application and drying of paint was carried out in accordance with the following procedures. The result is a green magnetic sheet. In this case, the thickness of the magnetic paint layer was 10 μm, and the coating weight was 14.0 g / m ² .

 (Procedure 1) The resin was dissolved in methyl ethyl ketone (MEK) at the concentration indicated in the table. 1, and magnetic powder was added to the solution. Then the resulting composition was dispersed for 1 hour in a grinder.

 (Procedure 2) To the dispersion were added blue paint, yellow paint and white paint manufactured by Mikuni Color Ltd., each of which was formed by the dispersion of pigment in IEC, in the ratio indicated in the table for composition (A). Then the whole composition was mixed until a magnetic green paint was obtained.

 (Procedure 3) Magnetic paint was applied to the film using a coating machine at a speed of 30 m / min and dried to obtain the above green magnetic sheet.

 Then, the resulting sheet was cut into pieces of 100 mm • 140 mm and aluminum was sprayed onto it using a vapor phase vacuum deposition apparatus manufactured by SINKU-RIKQ, INC. (model FA-504); thus, a two-color sheet was obtained, painted green from the side of the base film and silver from the opposite side.

In this case, the thickness of the sprayed layer was 0.05 μm, and, according to the measurement results of the two-color sheet after vacuum spraying, the weight of the aluminum sprayed layer together with the paint layer was 14.1 g / m ² .

 After that, the two-color sheet was magnetized together with the base film so that the green side of the two-color sheet became the N-pole, and the silver side became the S-pole, and then the two-color sheet was separated from the base film, so that a thin film was obtained. Then the thin film was crushed in a small mill (manufactured by Kyorisu Riko K.K., sample type SK-M3) and sieved; the result was a magnetic imaging material of particles ranging in size from 63 to 212 microns, painted in two colors - green and silver.

Then, isoparaffin with a viscosity of 2.0 MPa • s was mixed at 25 ^° C (manufactured by Esso Chemical Co. Ltd., trade name ISOPAR-M) as a dispersion medium and ethylene bis-12-hydroxystearic acid acidamide (ITON WAXJ-530 manufactured by Itoh Oil Chemical Co. Ltd.) as a thickener in a ratio of 70 parts by weight of the first and 30 parts by weight of the latter to form a dispersion. The dispersion was diluted with isoparaffin so that the ratio of isoparaffin to thickener was 407.92: 12.42 parts by weight. An antistatic agent (STADIS-450 manufactured by E. LDupont Co. Ltd.) was added to the diluted dispersion in an amount of 0.15% of the total weight. The result is a dispersion with a yield strength of 1.76 N / m ² and a viscosity of 16 MPa • s at 25 ^o C.

 The yield strength was determined by the method of reading the angle of rotation of the rotor when the dispersion was rotated at a low speed using a Brookfield viscometer (type BL manufactured by Tokyo Keiki Co. Ltd.). The second rotor attached to the specified type BL viscometer was used as the rotor itself.

 Further, regarding viscosity measurement, its value was measured under shear stress of 10 Pa using a voltage controlled rheometer (CSL-100 manufactured by Carri-Med. Ltd.).

 Then, a magnetic imaging material painted in green / silver was mixed with the dispersion in a ratio of 15 parts by weight of magnetic material per 100 parts by weight of the dispersion; the mixture was stirred until a liquid dispersion was obtained in which the magnetic imaging material was uniformly dispersed. The specific gravity of the liquid dispersion was 0.84.

 After this, the liquid dispersion was poured into the cells of a multicellular structure with partitions made of vinyl chloride resin. The cells of such a honeycomb structure had the shape of regular hexagons with a side of 3 mm and a height of 0.8 mm. The cells were glued on one side of a 0.12 mm thick PVC film. Then, the exposed surfaces of the honeycomb structure were coated with a 0.1 mm thick PVC film, which was glued to the honeycomb structure, so that the liquid dispersion was sealed in honeycombs; thus, an indicator panel was formed. In this case, the ratio of the total area of one color of the magnetic imaging material contained in the panel to the imaging surface of the panel was 622%. It was calculated as follows.

. Следовательно, если ячейки сот имеют сторону 3 мм,

.(1) The cell surface display area with the millimeter side of the cell is

. Therefore, if the cells of the cells have a side of 3 mm,

.

(2) On the other hand, the total area of a single-colored side of a magnetic imaging material is expressed as follows: S _particles = cell volume • specific gravity of the contained liquid • particle concentration: specific gravity of the particles: particle thickness. Therefore, S _particles = 7.794 • 0.8 • 0.84 • (15: 115) :( 14.1: 10.05): 0.01005 = 48.44 mm ² .

 (3) Accordingly, the ratio of the area of the layer of one surface of the magnetic imaging material to the area of the cells is: 48.44: 7.794 • 100 = 622 (%).

 The ratio between the internal volume V of one cell and the volume W of particles of the magnetic imaging material contained in the cell was W / V = 7.88%.

 Upon contact of the S-pole of the magnet with one side of the panel, a green surface formed, since the magnetic material in the cells, painted in two colors, was pulled to the front side of the panel and the particles were partially located on one another. Then, when the films were written on the surface of the PVC with the N-pole of the magnet, a clear silver-colored image with a metallic luster in the places where the N-pole of the magnet passed was obtained on the green display surface.

 Then, to erase the image, the S-pole of the magnet was again drawn along the silver-colored part of the panel, the particles of material turned to the panel surface with the silver side were inverted, and the surface turned green again.

Example 2
A liquid dispersion was obtained in the same manner as in Example 1, with the exception that the ratio in the mixture of the magnetic imaging material to 100 parts by weight of the dispersion changed by 2 parts by weight. The specific gravity of the liquid dispersion in this case was 0.80, and the ratio of the display area of one surface of the magnetic material to the display area of the panel was 89%; the calculation was performed by the method described above. Further, the ratio between the internal volume of one cell and the volume of magnetic material contained in one cell was 1.1%.

 Upon contact of the S-pole of the magnet with one side of the panel, a green surface formed, since the magnetic material in the cells, painted in two colors, was pulled to the front side of the panel and the particles were partially located on one another. Then, when the films were written on the surface of the PVC with the N-pole of the magnet, a clear silver-colored image with a metallic luster in the places where the N-pole of the magnet passed was obtained on the green display surface.

 Then, to erase the image, the S-pole of the magnet was again drawn over the silver-colored part of the panel, the particles of material turned to the panel surface with the silver side were inverted, and the surface turned green again.

Example 3
As in example 1, a green magnetic paint was prepared and applied to a 25 μm thick PET film, so that a green magnetic sheet was formed having a dry thickness of 9 μm and a coating weight of 12.59 g / m ² . Then, aluminum was sprayed onto the sheet by vapor deposition, similarly to Example 1. The thickness of the green magnetic sheet after aluminum deposition was 9.05 μm, and the total weight was 12.72 g / m ² .

 A liquid dispersion was obtained in the same manner as in Example 1, with the exception that the ratio in the mixture of the magnetic imaging material to 100 parts by weight of the dispersion was changed to 35 parts by weight. The specific gravity of the liquid dispersion in this case was 0.89, and the ratio of the display area of one surface of the magnetic material to the display area of the panel was 1458%; the calculation was performed by the method described above. Further, the ratio between the internal volume of one cell and the volume of magnetic material contained in one cell was 16.58%.

 Upon contact of the S-pole of the magnet with one side of the panel, a green surface formed, since the magnetic material in the cells, painted in two colors, was pulled to the front side of the panel and the particles were partially located on one another. Then, when the films were written on the surface of the PVC with the N-pole of the magnet, a clear silver-colored image with a metallic luster in the places where the N-pole of the magnet passed was obtained on the green display surface.

 Then, to erase the image, the S-pole of the magnet was again drawn over the silver-colored part of the panel, the particles of material turned to the panel surface with the silver side were inverted, and the surface turned green again.

Example 4
The transparent yellow paint of the composition indicated in Table 2 was applied to a 25 μm thick polyethylene terephthalate (PET) film and dried to obtain a transparent yellow paint layer having a dry thickness of 4 μm.

Then, a sputtered aluminum layer 0.05 μm thick was formed on it in the same manner as in Example 1, and the same green magnetic paint was applied to it, so that a green magnetic layer was formed having a dry thickness of 10 μm and a coating weight 13.99 g / m ² .

 As described above, a two-color sheet of gold was obtained on one side and green on the other. Then the sheet was magnetized with the formation of an N-pole on the green side and an S-pole on the gold side, the resulting sheet was crushed and sieved to obtain a magnetic imaging material with a particle size in the range from 63 to 212 μm, painted in two colors: green and gold.

 Then, the green / gold colored magnetic imaging material was mixed with the dispersion in a ratio of 15 parts by weight of the magnetic material per 100 parts by weight of the dispersion; the mixture was stirred until a liquid dispersion was obtained in which the magnetic imaging material was uniformly dispersed. The specific gravity of the liquid dispersion was 0.84 g.

 After that, the liquid dispersion was poured into cells of a multicellular structure in the form of honeycombs with partitions made of vinyl chloride resin. The cells of such a honeycomb structure had the shape of regular hexagons with a side of 3 mm and a height of 0.8 mm. The cells were glued on one side of a 0.12 mm thick PVC film. Then, the exposed surfaces of the honeycomb structure were coated with a 0.1 mm thick PVC film, which was glued to the honeycomb structure so that the liquid dispersion was sealed in honeycombs; thus, an indicator panel was formed. In this case, the ratio of the total area of one color of the magnetic imaging material contained in the panel to the imaging surface of the panel was 466%. It was calculated according to the method described above. The ratio between the internal volume of one cell and the particle volume of the magnetic imaging material contained in the cell was 8.2%.

 Upon contact of the S-pole of the magnet with one side of the panel, a green surface formed, since the magnetic material in the cells, painted in two colors, was pulled to the front side of the panel and the particles were partially located on one another. Then, when the films were written on the surface of the PVC with the N-pole of the magnet, a clear image of a gold color with a metallic luster in the places where the N-pole of the magnet passed on the green display surface.

 Then, to erase the image, the S-pole of the magnet was again drawn along the golden part of the panel, the material particles turned to the panel surface with the gold side were inverted, and the surface turned green again.

Example 5
The transparent blue paint of the composition indicated in Table 3 was applied to a PET film of 25 μm thickness and dried to obtain a transparent blue paint layer having a dry thickness of 4 μm.

Then, a sprayed aluminum layer 0.05 μm thick was formed on a layer of transparent blue paint in the same manner as in Example 1, and a magnetic paint of the composition indicated in Table 4 was applied to the sprayed layer, so that a magnetic layer with a dry thickness was formed form of 10 microns and a coating weight of 13.47 g / m ² .

After that, a yellow paint was applied to the magnetic layer of the composition indicated in the table. 5, so that a layer of yellow paint is formed having a dry thickness of 18 μm and a coating weight of 27.4 g / m ² ; thus, a two-color sheet was obtained.

 As described above, a two-color sheet of metallic blue was obtained on one side and yellow on the other. Then the sheet was magnetized with the formation of an N-pole on the blue side and an S-pole on the yellow side, as in Example 1, the resulting sheet was crushed and sieved to obtain a magnetic imaging material with a particle size in the range from 63 to 212 μm, painted in two colors: metallic blue and yellow.

 Then, the magnetic imaging material painted in metallic blue / yellow was mixed with the dispersion in a ratio of 15 parts by weight of magnetic material per 100 parts by weight of the dispersion; the mixture was stirred until a liquid dispersion was obtained in which the magnetic imaging material was uniformly dispersed. The specific gravity of the liquid dispersion was 0.84 g.

 After that, the liquid dispersion was poured into cells of a multicellular structure in the form of honeycombs, where the cells were made of vinyl chloride resin. The cells of the honeycomb structure were in the form of regular hexagons with a side of 3 mm and a height of 0.8 mm. The cells were glued on one side of a 0.12 mm thick PVC film. Then, the exposed surfaces of the honeycomb structure were coated with a 0.1 mm thick PVC film, which was glued to the honeycomb structure, so that the liquid dispersion was sealed in honeycombs; thus, an indicator panel was formed. In this case, the ratio of the total area of one color of the magnetic imaging material contained in the panel to the imaging surface of the panel was 186%. It was calculated according to the method described above. The ratio between the internal volume of one cell and the particle volume of the magnetic imaging material contained in the cell was 7.5%.

 Upon contact of the S-pole of the magnet with one side of the panel, as in examples 1 and 2, a blue surface with a metallic sheen was formed.

 Then, when the films were written on the surface of the PVC with the N-pole of the magnet, a clear yellow image was obtained on the blue surface with a metallic sheen in those places where the N-pole of the magnet passed.

 Then, to erase the image, the S-pole of the magnet was again drawn along the yellowed part of the panel, the particles of material turned to the panel surface with the yellow side were inverted, and the surface again turned blue with a metallic luster.

 Example for comparison 1.

As in Example 1, a green magnetic paint was prepared and applied to a 25 μm thick PET film, so that a green magnetic sheet was formed having a dry thickness of 6 μm and a coating weight of 8.39 g / m ² . Then aluminum was sprayed onto the sheet by vapor deposition, similarly to Example 1. The thickness of the green magnetic sheet after the aluminum was sprayed was 6.05 μm, and the total weight was 8.53 g / m ² .

 A liquid dispersion was obtained in the same manner as in Example 1, with the exception that the ratio in the mixture of the magnetic imaging material to 100 parts by weight of the dispersion was changed to 25 parts by weight. The specific gravity of the liquid dispersion in this case was 0.89, and the ratio of the display area of one surface of the magnetic material to the display area of the panel was 1632%; the calculation was performed by the method described above. Further, the ratio between the internal volume of one cell and the volume of magnetic material contained in one cell was 12.3%.

 Upon contact of the S-pole of the magnet with one side of the panel, a green surface formed, since the magnetic material in the cells, painted in two colors, was pulled to the front side of the panel and the particles were partially located on one another. Then, when the N-pole of the magnet was written on the surface of the PVC film, the particle inversion was insufficient, and a clear image was not obtained even in those places where it was carried out by a magnet.

 Example for comparison 2.

 A liquid dispersion was obtained in the same manner as in Example 5, with the exception that the ratio in the mixture of the magnetic imaging material to 100 parts by weight of the dispersion was changed to 50 parts by weight. The specific gravity of the liquid dispersion in this case was 0.94, and the ratio of the display area of one surface of the magnetic material to the display area of the panel was 529%; the calculation was performed by the method described above. Further, the ratio between the internal volume of one cell and the volume of magnetic material contained in one cell was 21.2%.

 Upon contact of the S-pole of the magnet with one side of the panel, a green surface formed, since the magnetic material in the cells, painted in two colors, was pulled to the front side of the panel and the particles were partially located on one another. Then, when the N-pole of the magnet was written on the surface of the PVC film, the particle inversion was insufficient, and a clear image was not obtained even in those places where it was carried out by a magnet.

 Example for comparison 3.

 A liquid dispersion was obtained in the same manner as in Example 1, with the exception that the ratio in the mixture of the magnetic imaging material to 100 parts by weight of the dispersion was changed to 1 part by weight. The specific gravity of the liquid dispersion in this case was 0.80, and the ratio of the display area of one surface of the magnetic material to the display area of the panel was 45%; the calculation was performed by the method described above. Further, the ratio between the internal volume of one cell and the volume of magnetic material contained in one cell was 0.6%.

 Upon contact of the S-pole of the magnet with one side of the panel, a green surface formed, since the magnetic material in the cells, painted in two colors, was pulled to the front side of the panel and the particles were partially located on one another. Then, when the films were written on the surface of the PVC with the N-pole of the magnet, the border between the green surface and the silver color of the written image was blurred, and a clear image was not obtained.

 Table 6 summarizes all the examples and comparative examples and gives their assessment.

Evaluation Standards
In the table. 1 shows the results of evaluating the properties of magnetic indicator panels with inversion of material made as described in the examples and examples for comparison.

 1. The assessment of the image forming property was carried out according to the following standard.

 (Procedure) N-pole and S-pole of a rubber magnet (an anisotropic rubber magnet magnetized so that it has magnetic poles parallel to the surface of the display panel; magnet length 150 mm, height 10 mm, thickness 2 mm) were alternately applied to the surface of the display panel and conducted them on this surface at a speed of 100 mm per second. The state of inversion of the magnetic material was observed visually.

(Assessment Standard)
Good: Magnetic material is uniformly inverted.

 bad: Particles of magnetic material interfere with each other, so the inversion is insufficient.

 2. The sharpness property was evaluated according to the following standard.

 (Procedure) N-pole and S-pole of a rubber magnet (an anisotropic rubber magnet magnetized so that it has magnetic poles parallel to the surface of the display panel; magnet length 150 mm, height 10 mm, thickness 2 mm) were alternately applied to the surface of the display panel , and then the magnet was moved, separating it, in the direction perpendicular to the surface of the display panel. In this case, the surfaces of the N-poles and S-poles of the magnetic imaging material that appeared on the surface of the panel were visually observed.

(Assessment Standard)
good: The boundary between the surfaces of the N-poles and S-poles of the magnetic imaging material is clear.

 bad: At the boundary between the surfaces of the N-poles and S-poles of the magnetic imaging material, color mixing is observed, the border is fuzzy.

 3. With regard to assessing the brightness of light color, for this purpose, indicator panels made by the methods described in the examples and comparative examples were evaluated by a group of 10 men and 10 women, i.e. only 20 people who were supposed to evaluate their sensations of light brightness, directivity, unevenness, etc.

 (Procedure) Using a rubber magnet over the entire surface of the display panel, the material was turned so that its surface with a thin metal layer was turned outward, and this side was visually observed by 20 people selected by random sampling. For the assessment, observers filled out questionnaires with three degrees of assessment (good, mediocre, bad).

 A general assessment, including the assessment of image formation, clarity and brightness of a light color, was carried out according to the following assessment standard.

(Assessment Standard)
□: very good
Oh, OK
x: unsuitable
The present invention provides a magnetic imaging material, providing increased contrast of the written image and having a relatively light color; It allows you to create an image of a metallic tone or pastel tone.

 All layers of magnetic imaging material are arranged sequentially in all embodiments of the invention, and in exactly the order as they are listed in the corresponding claims.

 The volume W in claim 1 is the volume of all particles of a magnetic imaging material located in the space between the substrates and the base.

The volume W ₁ in claim 10 of the claims is the volume of all particles of a magnetic imaging material located in a single cell. V ₁ in paragraph 10 of the formula represents the volume of a single cell.

The volume of W ₂ in paragraph 12 of the claims is the volume of all particles of magnetic imaging material located in the capsule. V ₂ in paragraph 12 of the formula represents the volume of the capsule.

Claims (15)

1. A magnetic display panel with material inversion, containing a base V having an internal volume, formed by two substrates hermetically connected around the perimeter with a space between them, one of which is the display surface of the display panel, at the base there is a liquid dispersion containing a dispersion medium, a thickener and a magnetic imaging material in the form of particles, the volume of which is W, and each particle of the magnetic imaging material consists of at least two layers and has two surfaces of different colors, one of which is magnetized as an N-pole, and the other as an S-pole, characterized in that one of the layers of the magnetic imaging material is made of metal, and the second is a magnetic layer, while the ratio between the volume of particles of the magnetic imaging of the material W and the internal volume of the base V is W / V from 1 to 17%, and the total surface area of the N-poles or the surface of the S-poles of the particles of the magnetic imaging material is at least 60% of the area of the imaging surface of the magnetic ind katornoy panel, or equal to it, or larger than the area of the display surface of the magnetic display panel is more than 15 times. 2. The magnetic indicator panel with the inversion of material according to claim 1, characterized in that the thickening agent is one or more substances selected from bis-amides of fatty acids having a hydroxyl group, hydrogenated castor oil and alkylamides of N-acylamino acids. 3. The magnetic indicator panel with the inversion of material according to claim 1 or 2, in which particles of the magnetic imaging material are obtained by cutting and grinding a sheet of a layered structure containing a metal layer and a magnetic layer, the magnetic layer containing magnetic particles dispersed in a composition containing synthetic resin and / or synthetic rubber. 4. The magnetic display panel with the inversion of material according to claim 1 or 2, in which particles of the magnetic display material are obtained by cutting or grinding a sheet of a layered structure containing a first transparent color layer, a metal layer, an unpainted magnetic layer, a second transparent color layer different from the first a transparent color layer of color, and the magnetic layer contains magnetic particles dispersed in a composition comprising a synthetic resin and / or synthetic rubber. 5. A magnetic display panel with an inversion of material 1 or 2, in which particles of a magnetic display material are obtained by cutting and grinding a sheet of a layered structure containing a first transparent color layer, a metal layer, a magnetic layer different from the first transparent color layer, color, the layer contains magnetic particles dispersed in a composition containing synthetic resin and / or synthetic rubber. 6. The magnetic display panel with the inversion of the material of claim 1 or 2, in which particles of the magnetic display material are obtained by cutting and grinding a layered structure containing a metal layer of the first color, an unpainted magnetic layer and a metal layer of the second color, the unpainted magnetic layer containing magnetic particles dispersed in a composition comprising a synthetic resin and / or synthetic rubber. 7. A magnetic indicator panel with material inversion according to any one of claims 1 to 6, characterized in that the metal layer is a metal layer sprayed in vacuum from the vapor phase. 8. A magnetic indicator panel with material inversion according to any one of claims 1 to 7, in which the liquid dispersion has a yield strength of 0.15 to 7.5 N / m ² and a viscosity of 3 to 350 MPa ^. from. 9. A magnetic indicator panel with material inversion according to any one of claims 1 to 8, in which the base further comprises a unit cell formed by a plurality of partitions located between the first and second substrates. 10. The magnetic display panel with the inversion of material according to claim 9, in which the second ratio between the volume W of the particles of the magnetic imaging material contained in the unit cell and the internal volume V of the unit cell is W / V from 1 to 17%. 11. A magnetic indicator panel with material inversion according to any one of claims 1 to 8, in which the liquid dispersion is contained in a capsule placed in the base. 12. The magnetic display panel with the inversion of material according to claim 11, in which the ratio between the volume W of the particles of the magnetic imaging material contained in the capsule and the internal volume V of the capsule is W / V from 1 to 17%. 13. A magnetic display panel with material inversion according to any one of claims 1-12, characterized in that the liquid dispersion further comprises an antistatic agent. 14. A magnetic inversion display panel containing a base V having an internal volume, formed by two substrates hermetically connected around the perimeter with a space between them, one of which is the display surface of the display panel, at the base is a liquid dispersion containing a dispersion medium, a thickener and a magnetic imaging material in the form of particles, the volume of which is W, and each particle of the magnetic imaging material consists of at least two layers and has two surfaces of different colors, one of which is magnetized as an N-pole, and the other as an S-pole, characterized in that the particles of the magnetic imaging material are obtained by cutting and grinding a layered structure that contains a magnetic layer and a metal layer different from the magnetic color layer , or optionally: a first transparent color layer, a metal layer, a magnetic layer, a second transparent color layer of a color different from the first transparent color layer, or a transparent color layer, a metal layer, a color magnetic layer the color different from the transparent color layer, the ratio between the particle volume of the magnetic imaging material W and the internal volume of the base V is W / V from 1 to 17%, and the total surface area of the N-poles or the surface of the S-poles of the particles of the magnetic imaging material is not less than 60% of the display surface of the magnetic display panel is either equal to it or exceeds the display surface of the magnetic display panel by no more than 15 times. 15. The magnetic indicator panel with the inversion of material according to 14, characterized in that the liquid dispersion further comprises an antistatic agent.

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